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https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import re import itertools import numpy as np import random random.seed(42) import mitiq from qiskit import QuantumCircuit, QuantumRegister from qiskit.ignis.mitigation import expectation_value # Pauli Twirling def pauli_twirling(circ: QuantumCircuit) -> QuantumCircuit: """ [internal function] This function takes a quantum circuit and return a new quantum circuit with Pauli Twirling around the CNOT gates. Args: circ: QuantumCircuit Returns: QuantumCircuit """ def apply_pauli(num: int, qb: int) -> str: if (num == 0): return f'' elif (num == 1): return f'x q[{qb}];\n' elif (num == 2): return f'y q[{qb}];\n' else: return f'z q[{qb}];\n' paulis = [(i,j) for i in range(0,4) for j in range(0,4)] paulis.remove((0,0)) paulis_map = [(0, 1), (3, 2), (3, 3), (1, 1), (1, 0), (2, 3), (2, 2), (2, 1), (2, 0), (1, 3), (1, 2), (3, 0), (3, 1), (0, 2), (0, 3)] new_circ = '' ops = circ.qasm().splitlines(True) #! split the quantum circuit into qasm operators for op in ops: if (op[:2] == 'cx'): # add Pauli Twirling around the CNOT gate num = random.randrange(len(paulis)) qbs = re.findall('q\[(.)\]', op) new_circ += apply_pauli(paulis[num][0], qbs[0]) new_circ += apply_pauli(paulis[num][1], qbs[1]) new_circ += op new_circ += apply_pauli(paulis_map[num][0], qbs[0]) new_circ += apply_pauli(paulis_map[num][1], qbs[1]) else: new_circ += op return QuantumCircuit.from_qasm_str(new_circ) def zne_wrapper(qcs, scale_factors = [1.0, 2.0, 3.0], pt = False): """ This function outputs the circuit list for zero-noise extrapolation. Args: qcs: List[QuantumCircuit], the input quantum circuits. scale_factors: List[float], to what extent the noise scales are investigated. pt: bool, whether add Pauli Twirling or not. Returns: folded_qcs: List[QuantumCircuit] """ folded_qcs = [] #! ZNE用の回路 for qc in qcs: folded_qcs.append([mitiq.zne.scaling.fold_gates_at_random(qc, scale) for scale in scale_factors]) #! ここでmitiqを使用 folded_qcs = list(itertools.chain(folded_qcs)) #! folded_qcsを平坦化 if pt: folded_qcs = [pauli_twirling(circ) for circ in folded_qcs] return folded_qcs def make_stf_basis(n, basis_elements = ["X","Y","Z"]): """ [internal function] This function outputs all the combinations of length n string for given basis_elements. When basis_elements is X, Y, and Z (default), the output becomes the n-qubit Pauli basis. Args: n: int basis_elements: List[str] Returns: basis: List[str] """ if n == 1: return basis_elements basis = [] for i in basis_elements: sub_basis = make_stf_basis(n - 1, basis_elements) basis += [i + j for j in sub_basis] return basis def reduce_hist(hist, poses): """ [internal function] This function returns the reduced histogram to the designated positions. Args: hist: Dict[str, float] poses: List[int] Returns: ret_hist: Dict[str, float] """ n = len(poses) ret_hist = {format(i, "0" + str(n) + "b"): 0 for i in range(1 << n)} for k, v in hist.items(): pos = "" for i in range(n): pos += k[poses[i]] ret_hist[pos] += v return ret_hist def make_stf_expvals(n, stf_hists): """ [internal function] This function create the expectations under expanded basis, which are used to reconstruct the density matrix. Args: n: int, the size of classical register in the measurement results. stf_hists: List[Dict[str, float]], the input State Tomography Fitter histograms. Returns: st_expvals: List[float], the output State Tomography expectation values. """ assert len(stf_hists) == 3 * n stf_basis = make_stf_basis(n, basis_elements=["X","Y","Z"]) st_basis = make_stf_basis(n, basis_elements=["I","X","Y","Z"]) stf_hists_dict = {basis: hist for basis, hist in zip(stf_basis, stf_hists)} st_hists_dict = {basis: stf_hists_dict.get(basis, None) for basis in st_basis} # remaining for basis in sorted(set(st_basis) - set(stf_basis)): if basis == "I" * n: continue reduction_poses = [] reduction_basis = "" for i, b in enumerate(basis): if b != "I": reduction_poses.append(n - 1 - i) # big endian reduction_basis += b # こっちはそのまま(なぜならラベルはlittle endianだから) else: reduction_basis += "Z" st_hists_dict[basis] = reduce_hist(stf_hists_dict[reduction_basis], reduction_poses) st_expvals = dict() for basis, hist in st_hists_dict.items(): if basis == "I" * n: st_expvals[basis] = 1.0 continue st_expvals[basis], _ = expectation_value(hist) return st_expvals def zne_decoder(n, result, scale_factors=[1.0, 2.0, 3.0], fac_type="lin"): """ This function applies the zero-noise extrapolation to the measured results and output the mitigated zero-noise expectation values. Args: n: int, the size of classical register in the measurement results. result: Result, the returned results from job. scale_factors: List[float], this should be the same as the zne_wrapper. fac_type: str, "lin" or "exp", whether to use LinFactory option or ExpFactory option in mitiq, to extrapolate the expectation values. Returns: zne_expvals: List[float], the mitigated zero-noise expectation values. """ hists = result.get_counts() num_scale_factors = len(scale_factors) assert len(hists) % num_scale_factors == 0 scale_wise_expvals = [] # num_scale_factors * 64 for i in range(num_scale_factors): scale_wise_hists = [hists[3 * j + i] for j in range(len(hists) // num_scale_factors)] st_expvals = make_stf_expvals(n, scale_wise_hists) scale_wise_expvals.append( list(st_expvals.values()) ) scale_wise_expvals = np.array(scale_wise_expvals) linfac = mitiq.zne.inference.LinearFactory(scale_factors) expfac = mitiq.zne.ExpFactory(scale_factors) zne_expvals = [] for i in range(4 ** n): if fac_type == "lin": zne_expvals.append( linfac.extrapolate(scale_factors, scale_wise_expvals[:, i]) ) else: zne_expvals.append( expfac.extrapolate(scale_factors, scale_wise_expvals[:, i]) ) return zne_expvals
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2 * dt, 0) qc.rz(2 * dt, 1) qc.h(1) qc.cx(1, 0) qc.rz(-2 * dt, 0) qc.rx(-2 * dt, 1) qc.rz(2 * dt, 1) qc.cx(1, 0) qc.h(1) qc.rz(2 * dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") def make_initial_state(qc, initial_state): """ logical qubit index little endian """ for i, state in enumerate(initial_state): if state == "1": qc.x(i) qc = QuantumCircuit(3) make_initial_state(qc, "101") qc.draw("mpl") def subspace_encoder(qc, targets): """ naive method, can be optimized for init state \|110> little endian """ n = qc.num_qubits qc.cx(targets[2],targets[1]) qc.cx(targets[1],targets[0]) def subspace_encoder_init110(qc, targets): """ optimized encoder for init state \|110> endian: \|q_0, q_1, q_2> (little endian) encode \|110> to \|0>\|10> """ n = qc.num_qubits qc.x(targets[0]) def subspace_decoder(qc, targets): """ naive method little endian """ n = qc.num_qubits qc.cx(targets[1], targets[0]) qc.cx(targets[2], targets[1]) qc = QuantumCircuit(3) make_initial_state(qc, "110") subspace_encoder_init110(qc, targets=[0,1,2]) qc.draw("mpl") def trotterize(qc, trot_gate, num_steps, targets): for _ in range(num_steps): qc.append(trot_gate, qargs = targets) qc = QuantumCircuit(3) make_initial_state(qc, "110") subspace_encoder_init110(qc, targets=[0,1,2]) qc.barrier() trotterize(qc, trotter_gate(np.pi / 6), 1, targets=[1, 2]) qc = transpile(qc, optimization_level = 3, basis_gates=["sx", "rz", "cx"]) qc.draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] st_qcs_list = [] # Number of trotter steps max_trotter_step = 50 ### CAN BE >= 4 trotter_steps = list(range(1, max_trotter_step + 1, 3)) for num_steps in trotter_steps: print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "101") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) st_qcs_list.append(t3_st_qcs) st_qcs_list[-1][-1].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") jobs = [] shots = 1 << 13 # Number of trotter steps for i, num_steps in enumerate(trotter_steps): print("trotter step: ", num_steps) # execute: reps = 1 job = execute(st_qcs_list[i], backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) print() # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') results = [] for job in jobs: results.append( job.result() ) mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) print(len(results), len(mit_results)) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^Zero^One).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition raw_fids = [] for result in results: fid = state_tomo(result, st_qcs) raw_fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) plt.clf() plt.style.use('ggplot') plt.figure(dpi=200) plt.title("state fidelity from Trotter step 1 to "+str(trotter_steps)) plt.plot(trotter_steps, raw_fids, label="raw fidelity") plt.plot(trotter_steps, fids, label="fidelity after QREM") plt.xlabel("number of trotter steps") plt.ylabel("fidelity") plt.grid(linestyle='dotted') for step, fid in zip(trotter_steps, raw_fids): print(step, fid) for step, fid in zip(trotter_steps, fids): print(step, fid)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers backend = Aer.get_backend("qasm_simulator") def make_initial_state(qc, initial_state): """ logical qubit index little endian """ for i, state in enumerate(initial_state): if state == "1": qc.x(i) def subspace_encoder(qc, targets): """ naive method, can be optimized for init state \|110> little endian """ n = qc.num_qubits qc.cx(targets[0],targets[1]) qc.cx(targets[2],targets[1]) qc.cx(targets[1],targets[2]) qc.cx(targets[0],targets[1]) qc.cx(targets[1],targets[0]) def subspace_encoder_init110(qc, targets): """ optimized encoder for init state \|110> endian: \|q_0, q_1, q_2> (little endian) encode \|110> to \|0>\|10> """ n = qc.num_qubits qc.x(targets[0]) def subspace_decoder(qc, targets): """ naive method little endian """ n = qc.num_qubits qc.cx(targets[1],targets[0]) qc.cx(targets[0],targets[1]) qc.cx(targets[1],targets[2]) qc.cx(targets[2],targets[1]) qc.cx(targets[0],targets[1]) # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # initial layout initial_layout = [5,3,1] qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) qc.x([1]) qc.barrier() subspace_encoder(qc, targets=[0, 1, 2]) # encode qc.measure_all() t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) t3_qc.draw("mpl") execute(qc, backend).result().get_counts()
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2 * dt, 0) qc.rz(2 * dt, 1) qc.h(1) qc.cx(1, 0) qc.rz(-2 * dt, 0) qc.rx(-2 * dt, 1) qc.rz(2 * dt, 1) qc.cx(1, 0) qc.h(1) qc.rz(2 * dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") def make_initial_state(qc, initial_state): """ logical qubit index little endian """ for i, state in enumerate(initial_state): if state == "1": qc.x(i) qc = QuantumCircuit(3) make_initial_state(qc, "101") qc.draw("mpl") def subspace_encoder(qc, targets): """ naive method, can be optimized for init state \|110> little endian """ n = qc.num_qubits qc.cx(targets[2],targets[1]) qc.cx(targets[1],targets[0]) def subspace_encoder_init110(qc, targets): """ optimized encoder for init state \|110> endian: \|q_0, q_1, q_2> (little endian) encode \|110> to \|0>\|10> """ n = qc.num_qubits qc.x(targets[0]) def subspace_decoder(qc, targets): """ naive method little endian """ n = qc.num_qubits qc.cx(targets[1], targets[0]) qc.cx(targets[2], targets[1]) qc = QuantumCircuit(3) make_initial_state(qc, "110") subspace_encoder_init110(qc, targets=[0,1,2]) qc.draw("mpl") def trotterize(qc, trot_gate, num_steps, targets): for _ in range(num_steps): qc.append(trot_gate, qargs = targets) qc = QuantumCircuit(3) make_initial_state(qc, "110") subspace_encoder_init110(qc, targets=[0,1,2]) qc.barrier() trotterize(qc, trotter_gate(np.pi / 6), 1, targets=[1, 2]) qc = transpile(qc, optimization_level = 3, basis_gates=["sx", "rz", "cx"]) qc.draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] st_qcs_list = [] # Number of trotter steps max_trotter_step = 50 ### CAN BE >= 4 trotter_steps = list(range(1, max_trotter_step + 1, 3)) for num_steps in trotter_steps: print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "101") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) st_qcs_list.append(t3_st_qcs) st_qcs_list[-1][-1].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") jobs = [] shots = 1 << 13 # Number of trotter steps for i, num_steps in enumerate(trotter_steps): print("trotter step: ", num_steps) # execute: reps = 1 job = execute(st_qcs_list[i], backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) print() # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') results = [] for job in jobs: results.append( job.result() ) mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) print(len(results), len(mit_results)) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^Zero^One).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition raw_fids = [] for result in results: fid = state_tomo(result, st_qcs) raw_fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) plt.clf() plt.style.use('ggplot') plt.figure(dpi=200) plt.title("state fidelity from Trotter step 1 to "+str(trotter_steps)) plt.plot(trotter_steps, raw_fids, label="raw fidelity") plt.plot(trotter_steps, fids, label="fidelity after QREM") plt.xlabel("number of trotter steps") plt.ylabel("fidelity") plt.grid(linestyle='dotted') for step, fid in zip(trotter_steps, raw_fids): print(step, fid) for step, fid in zip(trotter_steps, fids): print(step, fid)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2 * dt, 0) qc.rz(2 * dt, 1) qc.h(1) qc.cx(1, 0) qc.rz(-2 * dt, 0) qc.rx(-2 * dt, 1) qc.rz(2 * dt, 1) qc.cx(1, 0) qc.h(1) qc.rz(2 * dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") def make_initial_state(qc, initial_state): """ logical qubit index little endian """ for i, state in enumerate(initial_state): if state == "1": qc.x(i) qc = QuantumCircuit(3) make_initial_state(qc, "101") qc.draw("mpl") def subspace_encoder(qc, targets): """ naive method, can be optimized for init state \|110> little endian """ n = qc.num_qubits qc.cx(targets[2],targets[1]) qc.cx(targets[1],targets[0]) qc.cx(targets[0],targets[2]) def subspace_encoder_init110(qc, targets): """ optimized encoder for init state \|110> endian: \|q_0, q_1, q_2> (little endian) encode \|110> to \|0>\|10> """ n = qc.num_qubits qc.x(targets[0]) def subspace_decoder(qc, targets): """ naive method little endian """ n = qc.num_qubits qc.cx(targets[0], targets[2]) qc.cx(targets[1], targets[0]) qc.cx(targets[2], targets[1]) qc = QuantumCircuit(3) make_initial_state(qc, "110") subspace_encoder_init110(qc, targets=[0,1,2]) qc.draw("mpl") def trotterize(qc, trot_gate, num_steps, targets): for _ in range(num_steps): qc.append(trot_gate, qargs = targets) qc = QuantumCircuit(3) make_initial_state(qc, "110") subspace_encoder_init110(qc, targets=[0,1,2]) qc.barrier() trotterize(qc, trotter_gate(np.pi / 6), 1, targets=[1, 2]) qc = transpile(qc, optimization_level = 3, basis_gates=["sx", "rz", "cx"]) qc.draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) qc.h([1,2]) qc.cx(0,2) qc.barrier() subspace_encoder(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, 10, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0, 1, 2]) # decode qc = qc.bind_parameters({dt: target_time / 2}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) t3_qc.draw("mpl") st_qcs_list = [] # Number of trotter steps max_trotter_step = 50 ### CAN BE >= 4 trotter_steps = list(range(1, max_trotter_step + 1, 3)) for num_steps in trotter_steps: print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "101") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) st_qcs_list.append(t3_st_qcs) st_qcs_list[-1][-1].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") jobs = [] shots = 1 << 13 # Number of trotter steps for i, num_steps in enumerate(trotter_steps): print("trotter step: ", num_steps) # execute: reps = 1 job = execute(st_qcs_list[i], backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) print() # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') results = [] for job in jobs: results.append( job.result() ) mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) print(len(results), len(mit_results)) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^Zero^One).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition raw_fids = [] for result in results: fid = state_tomo(result, st_qcs) raw_fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) plt.clf() plt.style.use('ggplot') plt.figure(dpi=200) plt.title("state fidelity from Trotter step 1 to "+str(trotter_steps)) plt.plot(trotter_steps, raw_fids, label="raw fidelity") plt.plot(trotter_steps, fids, label="fidelity after QREM") plt.xlabel("number of trotter steps") plt.ylabel("fidelity") plt.grid(linestyle='dotted') for step, fid in zip(trotter_steps, raw_fids): print(step, fid) for step, fid in zip(trotter_steps, fids): print(step, fid)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import qiskit from qiskit import * from qiskit import Aer import pandas as pd from qiskit.providers.aer.noise.noise_model import NoiseModel from qiskit.test.mock import * from qiskit.providers.aer import AerSimulator, QasmSimulator from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter import itertools import mitiq import argparse import cma import os import sys from qiskit import IBMQ import pickle import random import re from pprint import pprint #! ここからmainの実行処理 IBMQ.load_account() # provider = IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') print("provider:", provider) L = 3 p = 2 dt = 1.0 tf = 20 shots = 8192 #TODO 外部実装 def TwirlCircuit(circ: str) -> QuantumCircuit: #! qasm ベタ書き def apply_pauli(num: int, qb: int) -> str: if (num == 0): return f'id q[{qb}];\n' elif (num == 1): return f'x q[{qb}];\n' elif (num == 2): return f'y q[{qb}];\n' else: return f'z q[{qb}];\n' paulis = [(i,j) for i in range(0,4) for j in range(0,4)] paulis.remove((0,0)) paulis_map = [(0, 1), (3, 2), (3, 3), (1, 1), (1, 0), (2, 3), (2, 2), (2, 1), (2, 0), (1, 3), (1, 2), (3, 0), (3, 1), (0, 2), (0, 3)] new_circ = '' ops = circ.qasm().splitlines(True) #! 生のqasmコードを持ってきてる: オペレータに分解 for op in ops: if (op[:2] == 'cx'): # can add for cz, etc. num = random.randrange(len(paulis)) qbs = re.findall('q\[(.)\]', op) new_circ += apply_pauli(paulis[num][0], qbs[0]) new_circ += apply_pauli(paulis[num][1], qbs[1]) new_circ += op new_circ += apply_pauli(paulis_map[num][0], qbs[0]) new_circ += apply_pauli(paulis_map[num][1], qbs[1]) else: new_circ += op return qiskit.circuit.QuantumCircuit.from_qasm_str(new_circ) #! convert 完了 def TrotterEvolveCircuit(dt, nt, init): """ Implements trotter evolution of the Heisenberg hamiltonian using the circuit from https://arxiv.org/pdf/1906.06343.pdf #! 要チェック :param tf: time to evolve to #! dt * nt = tf ??? :param nt: number of trotter steps to use :param init: initial state for the trotter evolution. Should be another Qiskit circuit 外部変数: L """ # def get_angles(a, b, c): # return (np.pi/2 - 2c, 2a - np.pi/2, np.pi/2 - 2b) def get_angles(a): #! 角度計算, aはalpha, return値タプルの0はtheta, 1はphi, 2はlambd = theta return (np.pi/2 - 2a, 2a - np.pi/2, np.pi/2 - 2a) def N(cir, qb0, qb1): #! fig 4を実装: thetaとphiとlambdはglobal変数 #! cnotのdepthは3 cir.rz(-np.pi/2, qb1) cir.cnot(qb1, qb0) cir.rz(theta, qb0) cir.ry(phi, qb1) cir.cnot(qb0, qb1) cir.ry(lambd, qb1) cir.cnot(qb1, qb0) cir.rz(np.pi/2, qb0) return cir #! dtはtrotter step size ← step sizeとは？？？ (default: 0.25) theta, phi, lambd = get_angles(-dt/4) #! why divided by 4??? 少なくとも時間間隔ではある circ = init for i in range(nt): #! ntはTrotterステップ数 (ここではcnotが深さnt * 3かかる) # even (odd indices) if (L % 2 == 0): #! Lはsystem size # UEven for i in range(1, L-1, 2): # L for periodic bdy conditions circ = N(circ, i, (i+1)%L) # UOdd for i in range(0, L-1, 2): circ = N(circ, i, (i+1)%L) else: # UEven for i in range(1, L, 2): circ = N(circ, i, (i+1)%L) # UOdd for i in range(0, L-1, 2): circ = N(circ, i, (i+1)%L) # UBdy # circ = N(circ, L-1, 0) return circ #! convert完了 def AnsatzCircuit(params: list, p: int) -> QuantumCircuit: """ Implements HVA ansatz using circuits from https://arxiv.org/pdf/1906.06343.pdf #! 要チェック #! HVA := Hamiltonian Variational Ansatz :param params: parameters to parameterize circuit :param p: depth of the ansatz 外部変数: L, p """ circ = QuantumCircuit(L) #! L = system size def get_angles(a): #! 回転角度の計算 (肩に乗せるやつ) return (np.pi/2 - 2a, 2a - np.pi/2, np.pi/2 - 2a) def N(cir, angles, qb0, qb1): #! angles = (theta, phi, lambd) cir.rz(-np.pi/2, qb1) cir.cnot(qb1, qb0) cir.rz(angles[0], qb0) cir.ry(angles[1], qb1) cir.cnot(qb0, qb1) cir.ry(angles[2], qb1) cir.cnot(qb1, qb0) cir.rz(np.pi/2, qb0) return cir for i in range(p): if (L % 2 == 0): for j in range(1, L-1, 2): # L for periodic bdy conditions #! periodicなので、Lで割って、0とn-1にまたがる回路が存在する circ = N(circ, get_angles(-params[((L-1)i)+j]/4), j, (j+1)%L) for j in range(0, L-1, 2): circ = N(circ, get_angles(-params[((L-1)i)+j]/4), j, (j+1)%L) else: for j in range(1, L, 2): circ = N(circ, get_angles(-params[((L-1)i)+j]/4), j, (j+1)%L) for j in range(0, L-1, 2): circ = N(circ, get_angles(-params[((L-1)i)+j]/4), j, (j+1)%L) # circ = N(circ, get_angles(-params[(Li)+L-1]/4), L-1, 0) # boundary return circ #TODO reverse_bitを適宜挟む def ReorderBasis(circ): """ #! changing the big endian to little endian #! unnecessary function: equal to reverse_bit() method Reorders basis so that 0th qubit is on the left side of the tensor product :param circ: circuit to reorder, can also be a vector """ if (isinstance(circ, qiskit.circuit.quantumcircuit.QuantumCircuit)): for i in range(L//2): circ.swap(i, L-i-1) return circ else: perm = np.eye(2L) for i in range(1, 2L//2): perm[:, [i, 2L-i-1]] = perm[:, [2L-i-1, i]] return perm @ circ #TODO VTCとは別実装?→ no, 同じ実装に。 def SimulateAndReorder(circ): """ #! execution wrapper Executes a circuit using the statevector simulator and reorders basis to match with standard """ circ = ReorderBasis(circ) backend = Aer.get_backend('statevector_simulator') return execute(circ, backend).result().get_statevector() #TODO def Simulate(circ): """ #! execution wrapper Executes a circuit using the statevector simulator. Doesn't reorder -- which is needed for intermediate steps in the VTC """ backend = Aer.get_backend('statevector_simulator') return execute(circ, backend).result().get_statevector() #TODO def LoschmidtEchoExecutor(circuits, backend, shots, filter): """ #! 回路を実行 Returns the expectation value to be mitigated. :param circuit: Circuit to run. #! ここでのcircuitsは :param backend: backend to run the circuit on :param shots: Number of times to execute the circuit to compute the expectation value. :param fitter: measurement error mitigator """ # circuits = [TwirlCircuit(circ) for circ in circuits] scale_factors = [1.0, 2.0, 3.0] #! ZNEのノイズスケーリングパラメタ folded_circuits = [] #! ZNE用の回路 for circuit in circuits: folded_circuits.append([mitiq.zne.scaling.fold_gates_at_random(circuit, scale) for scale in scale_factors]) #! ここでmitiqを使用 folded_circuits = list(itertools.chain(folded_circuits)) #! folded_circuitsを平坦化 folded_circuits = [TwirlCircuit(circ) for circ in folded_circuits] #! 後からPauli Twirlingを施す! print("length of circuit in job", len(folded_circuits)) #! jobを投げる job = qiskit.execute( experiments=folded_circuits, backend=backend, optimization_level=0, shots=shots ) print("casted job") c = ['1','1','0'] #! これをpermutationする # c = [str((1 + (-1)(i+1)) // 2) for i in range(L)] c = ''.join(c)[::-1] #! endianを反転 (big endianへ) res = job.result() if (filter is not None): #! QREM res = filter.apply(res) print("retrieved job") all_counts = [job.result().get_counts(i) for i in range(len(folded_circuits))] expectation_values = [] for counts in all_counts: total_allowed_shots = [counts.get(''.join(p)) for p in set(itertools.permutations(c))] #! ここでcをpermutationしている total_allowed_shots = sum([0 if x is None else x for x in total_allowed_shots]) if counts.get(c) is None: expectation_values.append(0) else: expectation_values.append(counts.get(c)/total_allowed_shots) # expectation_values = [counts.get(c) / shots for counts in all_counts] zero_noise_values = [] if isinstance(backend, qiskit.providers.aer.backends.qasm_simulator.QasmSimulator): # exact_sim for i in range(len(circuits)): zero_noise_values.append(np.mean(expectation_values[ilen(scale_factors):(i+1)len(scale_factors)])) else: #device_sim, real_device fac = mitiq.zne.inference.LinearFactory(scale_factors) for i in range(len(circuits)): zero_noise_values.append(fac.extrapolate(scale_factors, expectation_values[ilen(scale_factors):(i+1)len(scale_factors)])) print("zero_noise_values") pprint(zero_noise_values) print() return zero_noise_values #TODO def LoschmidtEchoCircuit(params, U_v, U_trot, init, p): """ #! 回路を作成 Cost function using the Loschmidt Echo. Just using statevectors currently -- can rewrite using shots :param params: parameters new variational circuit that represents U_trot U_v \| init >. Need dagger for cost function :param U_v: variational circuit that stores the state before the trotter step :param U_trot: trotter step :param init: initial state :param p: number of ansatz steps """ U_v_prime = AnsatzCircuit(params, p) circ = init + U_v + U_trot + U_v_prime.inverse() circ.measure_all() return circ def LoschmidtEcho(params, U_v, U_trot, init, p, backend, shots, filter): """ #! 実行パート """ circs = [] for param in params: circs.append(LoschmidtEchoCircuit(param, U_v, U_trot, init, p)) #! 回路を作成 print("length of circuits without zne:", len(circs)) res = LoschmidtEchoExecutor(circs, backend, shots, filter) #! 回路を実行 return abs(1 - np.array(res)) def LoschmidtEchoExact(params, U_v, U_trot, init, p): """ #! unused function """ U_v_prime = AnsatzCircuit(params, p) circ = init + U_v + U_trot + U_v_prime.inverse() circ_vec = Simulate(circ) init_vec = Simulate(init) return 1 - abs(np.conj(circ_vec) @ init_vec)2 def CMAES(U_v, U_trot, init, p, backend, shots, filter): """ #! 実行 + 最適化パート """ init_params = np.random.uniform(0, 2np.pi, (L-1)p) es = cma.CMAEvolutionStrategy(init_params, np.pi/2) es.opts.set({'ftarget':5e-3, 'maxiter':1000}) # es = pickle.load(open(f'./results_{L}/optimizer_dump', 'rb')) while not es.stop(): #! 最適化パート # solutions = es.ask(25) # ! 25 = number of returned solutions solutions = es.ask(10) print("solutions") pprint(solutions) es.tell(solutions, LoschmidtEcho(solutions, U_v, U_trot, init, p, backend, shots, filter)) #! 実行パート # es.tell(solutions, LoschmidtEchoExact(solutions, U_v, U_trot, init, p)) #! 実行パート es.disp() open(f'./results_{L}/optimizer_dump', 'wb').write(es.pickle_dumps()) return es.result_pretty() def VTC(tf, dt, p, init, backend, shots, filter): """ #! tf: 総経過時間 #! dt: trotter step size: 時間間隔 #! p: ansatzのステップ数 """ VTCParamList = [np.zeros((L-1)p)] #! デフォルトのパラメタ(初期値) VTCStepList = [SimulateAndReorder(init.copy())] #! type: List[Statevector] # TrotterFixStepList = [init] TimeStep = [0] if (os.path.exists(f'./results_{L}/VTD_params_{tf}_{L}_{p}_{dt}_{shots}.csv')): #! 2巡目からこっち VTCParamList = pd.read_csv(f'./results_{L}/VTD_params_{tf}_{L}_{p}_{dt}_{shots}.csv', index_col=0) VTCStepList = pd.read_csv(f'./results_{L}/VTD_results_{tf}_{L}_{p}_{dt}_{shots}.csv', index_col=0) temp = VTCParamList.iloc[-1] print(temp, "th time interval") U_v = AnsatzCircuit(temp, p) else: #! 最初はこっちに入る VTCParamList = pd.DataFrame(np.array(VTCParamList), index=np.array(TimeStep)) VTCStepList = pd.DataFrame(np.array(VTCStepList), index=np.array(TimeStep)) print("0 th time interval") print() U_v = QuantumCircuit(L) ts = VTCParamList.index #! 時間間隔 U_trot = TrotterEvolveCircuit(dt, p, QuantumCircuit(L)) #! Trotter分解のunitaryを作る print() print("start CMAES") print() res = CMAES(U_v, U_trot, init, p, backend, shots, filter) #! ここでプロセスを実行！！！！ print() print("res") pprint(res) #! 新しいループ結果を追加し、tsを更新 res = res.xbest # ! best solution evaluated print("res.xbest") pprint(res) VTCParamList.loc[ts[-1]+(dtp)] = np.array(res) VTCStepList.loc[ts[-1]+(dtp)] = np.array(SimulateAndReorder(init + AnsatzCircuit(res, p))) ts = VTCParamList.index # VTCParamList = pd.DataFrame(np.array(VTCParamList), index=np.array(TimeStep)) # VTCStepList = pd.DataFrame(np.array(VTCStepList), index=np.array(TimeStep)) #! csvファイルを更新 VTCParamList.to_csv(f'./results_{L}/VTD_params_{tf}_{L}_{p}_{dt}_{shots}.csv') VTCStepList.to_csv(f'./results_{L}/VTD_results_{tf}_{L}_{p}_{dt}_{shots}.csv') if (ts[-1] >= tf): return else: print("next step") VTC(tf, dt, p, init, backend, shots, filter) #! ここからQREM回路 qr = QuantumRegister(L) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # device_backend = FakeJakarta() # device_sim = AerSimulator.from_backend(device_backend) real_device = provider.get_backend('ibmq_jakarta') noise_model = NoiseModel.from_backend(real_device) device_sim = QasmSimulator(method='statevector', noise_model=noise_model) exact_sim = Aer.get_backend('qasm_simulator') # QasmSimulator(method='statevector') t_qc = transpile(meas_calibs) qobj = assemble(t_qc, shots=8192) # cal_results = real_device.run(qobj, shots=8192).result() cal_results = device_sim.run(qobj, shots=8192).result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') print("qrem done") # np.around(meas_fitter.cal_matrix, decimals=2) init = QuantumCircuit(L) # c = [str((1 + (-1)*(i+1)) // 2) for i in range(L)] c = ['1','1','0'] #! なぜinitial stateが110なの？？？？？？？もしかしてopen science prizeを意識??? #! けどループでこのプログラムが実行されるたびにここが\|110>だとおかしくないか？ for q in range(len(c)): if (c[q] == '1'): init.x(q) #! ここまでQREM回路 nt = int(np.ceil(tf / (dt p))) # f = open(f'./results_{L}/logging.txt', 'a') # sys.stdout = f #! tf: シミュレーションの(経過)時間 #! dt: trotter分解のステップ数 #! p: ansatzのステップ数 (論文中のL) # VTC(tf, dt, p, init, real_device, shots, meas_fitter.filter) #! mainの処理 print("vtc start!!!! \n\n\n") VTC(tf, dt, p, init, device_sim, shots, meas_fitter.filter) #! mainの処理 # f.close()
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import qiskit from qiskit import * from qiskit import Aer import pandas as pd from qiskit.providers.aer.noise.noise_model import NoiseModel from qiskit.test.mock import * from qiskit.providers.aer import AerSimulator, QasmSimulator from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter import itertools import mitiq import argparse import cma import os import sys from qiskit import IBMQ import pickle import random import re from pprint import pprint #! ここからmainの実行処理 IBMQ.load_account() # provider = IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') print("provider:", provider) L = 3 p = 2 dt = 1.0 tf = 20 shots = 8192 #TODO 外部実装 def TwirlCircuit(circ: str) -> QuantumCircuit: #! qasm ベタ書き def apply_pauli(num: int, qb: int) -> str: if (num == 0): return f'id q[{qb}];\n' elif (num == 1): return f'x q[{qb}];\n' elif (num == 2): return f'y q[{qb}];\n' else: return f'z q[{qb}];\n' paulis = [(i,j) for i in range(0,4) for j in range(0,4)] paulis.remove((0,0)) paulis_map = [(0, 1), (3, 2), (3, 3), (1, 1), (1, 0), (2, 3), (2, 2), (2, 1), (2, 0), (1, 3), (1, 2), (3, 0), (3, 1), (0, 2), (0, 3)] new_circ = '' ops = circ.qasm().splitlines(True) #! 生のqasmコードを持ってきてる: オペレータに分解 for op in ops: if (op[:2] == 'cx'): # can add for cz, etc. num = random.randrange(len(paulis)) qbs = re.findall('q\[(.)\]', op) new_circ += apply_pauli(paulis[num][0], qbs[0]) new_circ += apply_pauli(paulis[num][1], qbs[1]) new_circ += op new_circ += apply_pauli(paulis_map[num][0], qbs[0]) new_circ += apply_pauli(paulis_map[num][1], qbs[1]) else: new_circ += op return qiskit.circuit.QuantumCircuit.from_qasm_str(new_circ) #! convert 完了 def TrotterEvolveCircuit(dt, nt, init): """ Implements trotter evolution of the Heisenberg hamiltonian using the circuit from https://arxiv.org/pdf/1906.06343.pdf #! 要チェック :param tf: time to evolve to #! dt * nt = tf ??? :param nt: number of trotter steps to use :param init: initial state for the trotter evolution. Should be another Qiskit circuit 外部変数: L """ # def get_angles(a, b, c): # return (np.pi/2 - 2c, 2a - np.pi/2, np.pi/2 - 2b) def get_angles(a): #! 角度計算, aはalpha, return値タプルの0はtheta, 1はphi, 2はlambd = theta return (np.pi/2 - 2a, 2a - np.pi/2, np.pi/2 - 2a) def N(cir, qb0, qb1): #! fig 4を実装: thetaとphiとlambdはglobal変数 #! cnotのdepthは3 cir.rz(-np.pi/2, qb1) cir.cnot(qb1, qb0) cir.rz(theta, qb0) cir.ry(phi, qb1) cir.cnot(qb0, qb1) cir.ry(lambd, qb1) cir.cnot(qb1, qb0) cir.rz(np.pi/2, qb0) return cir #! dtはtrotter step size ← step sizeとは？？？ (default: 0.25) theta, phi, lambd = get_angles(-dt/4) #! why divided by 4??? 少なくとも時間間隔ではある circ = init for i in range(nt): #! ntはTrotterステップ数 (ここではcnotが深さnt * 3かかる) # even (odd indices) if (L % 2 == 0): #! Lはsystem size # UEven for i in range(1, L-1, 2): # L for periodic bdy conditions circ = N(circ, i, (i+1)%L) # UOdd for i in range(0, L-1, 2): circ = N(circ, i, (i+1)%L) else: # UEven for i in range(1, L, 2): circ = N(circ, i, (i+1)%L) # UOdd for i in range(0, L-1, 2): circ = N(circ, i, (i+1)%L) # UBdy # circ = N(circ, L-1, 0) return circ #! convert完了 def AnsatzCircuit(params: list, p: int) -> QuantumCircuit: """ Implements HVA ansatz using circuits from https://arxiv.org/pdf/1906.06343.pdf #! 要チェック #! HVA := Hamiltonian Variational Ansatz :param params: parameters to parameterize circuit :param p: depth of the ansatz 外部変数: L, p """ circ = QuantumCircuit(L) #! L = system size def get_angles(a): #! 回転角度の計算 (肩に乗せるやつ) return (np.pi/2 - 2a, 2a - np.pi/2, np.pi/2 - 2a) def N(cir, angles, qb0, qb1): #! angles = (theta, phi, lambd) cir.rz(-np.pi/2, qb1) cir.cnot(qb1, qb0) cir.rz(angles[0], qb0) cir.ry(angles[1], qb1) cir.cnot(qb0, qb1) cir.ry(angles[2], qb1) cir.cnot(qb1, qb0) cir.rz(np.pi/2, qb0) return cir for i in range(p): if (L % 2 == 0): for j in range(1, L-1, 2): # L for periodic bdy conditions #! periodicなので、Lで割って、0とn-1にまたがる回路が存在する circ = N(circ, get_angles(-params[((L-1)i)+j]/4), j, (j+1)%L) for j in range(0, L-1, 2): circ = N(circ, get_angles(-params[((L-1)i)+j]/4), j, (j+1)%L) else: for j in range(1, L, 2): circ = N(circ, get_angles(-params[((L-1)i)+j]/4), j, (j+1)%L) for j in range(0, L-1, 2): circ = N(circ, get_angles(-params[((L-1)i)+j]/4), j, (j+1)%L) # circ = N(circ, get_angles(-params[(Li)+L-1]/4), L-1, 0) # boundary return circ #TODO reverse_bitを適宜挟む def ReorderBasis(circ): """ #! changing the big endian to little endian #! unnecessary function: equal to reverse_bit() method Reorders basis so that 0th qubit is on the left side of the tensor product :param circ: circuit to reorder, can also be a vector """ if (isinstance(circ, qiskit.circuit.quantumcircuit.QuantumCircuit)): for i in range(L//2): circ.swap(i, L-i-1) return circ else: perm = np.eye(2L) for i in range(1, 2L//2): perm[:, [i, 2L-i-1]] = perm[:, [2L-i-1, i]] return perm @ circ #TODO VTCとは別実装?→ no, 同じ実装に。 def SimulateAndReorder(circ): """ #! execution wrapper Executes a circuit using the statevector simulator and reorders basis to match with standard """ circ = ReorderBasis(circ) backend = Aer.get_backend('statevector_simulator') return execute(circ, backend).result().get_statevector() #TODO def Simulate(circ): """ #! execution wrapper Executes a circuit using the statevector simulator. Doesn't reorder -- which is needed for intermediate steps in the VTC """ backend = Aer.get_backend('statevector_simulator') return execute(circ, backend).result().get_statevector() #TODO def LoschmidtEchoExecutor(circuits, backend, shots, filter): """ #! 回路を実行 Returns the expectation value to be mitigated. :param circuit: Circuit to run. #! ここでのcircuitsは :param backend: backend to run the circuit on :param shots: Number of times to execute the circuit to compute the expectation value. :param fitter: measurement error mitigator """ # circuits = [TwirlCircuit(circ) for circ in circuits] scale_factors = [1.0, 2.0, 3.0] #! ZNEのノイズスケーリングパラメタ folded_circuits = [] #! ZNE用の回路 for circuit in circuits: folded_circuits.append([mitiq.zne.scaling.fold_gates_at_random(circuit, scale) for scale in scale_factors]) #! ここでmitiqを使用 folded_circuits = list(itertools.chain(folded_circuits)) #! folded_circuitsを平坦化 folded_circuits = [TwirlCircuit(circ) for circ in folded_circuits] #! 後からPauli Twirlingを施す! print("length of circuit in job", len(folded_circuits)) #! jobを投げる job = qiskit.execute( experiments=folded_circuits, backend=backend, optimization_level=0, shots=shots ) print("casted job") c = ['1','1','0'] #! これをpermutationする # c = [str((1 + (-1)(i+1)) // 2) for i in range(L)] c = ''.join(c)[::-1] #! endianを反転 (big endianへ) res = job.result() if (filter is not None): #! QREM res = filter.apply(res) print("retrieved job") all_counts = [job.result().get_counts(i) for i in range(len(folded_circuits))] expectation_values = [] for counts in all_counts: total_allowed_shots = [counts.get(''.join(p)) for p in set(itertools.permutations(c))] #! ここでcをpermutationしている total_allowed_shots = sum([0 if x is None else x for x in total_allowed_shots]) if counts.get(c) is None: expectation_values.append(0) else: expectation_values.append(counts.get(c)/total_allowed_shots) # expectation_values = [counts.get(c) / shots for counts in all_counts] zero_noise_values = [] if isinstance(backend, qiskit.providers.aer.backends.qasm_simulator.QasmSimulator): # exact_sim for i in range(len(circuits)): zero_noise_values.append(np.mean(expectation_values[ilen(scale_factors):(i+1)len(scale_factors)])) else: #device_sim, real_device fac = mitiq.zne.inference.LinearFactory(scale_factors) for i in range(len(circuits)): zero_noise_values.append(fac.extrapolate(scale_factors, expectation_values[ilen(scale_factors):(i+1)len(scale_factors)])) print("zero_noise_values") pprint(zero_noise_values) print() return zero_noise_values #TODO def LoschmidtEchoCircuit(params, U_v, U_trot, init, p): """ #! 回路を作成 Cost function using the Loschmidt Echo. Just using statevectors currently -- can rewrite using shots :param params: parameters new variational circuit that represents U_trot U_v \| init >. Need dagger for cost function :param U_v: variational circuit that stores the state before the trotter step :param U_trot: trotter step :param init: initial state :param p: number of ansatz steps """ U_v_prime = AnsatzCircuit(params, p) circ = init + U_v + U_trot + U_v_prime.inverse() circ.measure_all() return circ def LoschmidtEcho(params, U_v, U_trot, init, p, backend, shots, filter): """ #! 実行パート """ circs = [] for param in params: circs.append(LoschmidtEchoCircuit(param, U_v, U_trot, init, p)) #! 回路を作成 print("length of circuits without zne:", len(circs)) res = LoschmidtEchoExecutor(circs, backend, shots, filter) #! 回路を実行 return abs(1 - np.array(res)) def LoschmidtEchoExact(params, U_v, U_trot, init, p): """ #! unused function """ U_v_prime = AnsatzCircuit(params, p) circ = init + U_v + U_trot + U_v_prime.inverse() circ_vec = Simulate(circ) init_vec = Simulate(init) return 1 - abs(np.conj(circ_vec) @ init_vec)2 def CMAES(U_v, U_trot, init, p, backend, shots, filter): """ #! 実行 + 最適化パート """ init_params = np.random.uniform(0, 2np.pi, (L-1)p) es = cma.CMAEvolutionStrategy(init_params, np.pi/2) es.opts.set({'ftarget':5e-3, 'maxiter':1000}) # es = pickle.load(open(f'./results_{L}/optimizer_dump', 'rb')) while not es.stop(): #! 最適化パート # solutions = es.ask(25) # ! 25 = number of returned solutions solutions = es.ask(1) print("solutions") pprint(solutions) es.tell(solutions, LoschmidtEcho(solutions, U_v, U_trot, init, p, backend, shots, filter)) #! 実行パート # es.tell(solutions, LoschmidtEchoExact(solutions, U_v, U_trot, init, p)) #! 実行パート es.disp() open(f'./results_{L}/optimizer_dump', 'wb').write(es.pickle_dumps()) return es.result_pretty() def VTC(tf, dt, p, init, backend, shots, filter): """ #! tf: 総経過時間 #! dt: trotter step size: 時間間隔 #! p: ansatzのステップ数 """ VTCParamList = [np.zeros((L-1)p)] #! デフォルトのパラメタ(初期値) VTCStepList = [SimulateAndReorder(init.copy())] #! type: List[Statevector] # TrotterFixStepList = [init] TimeStep = [0] if (os.path.exists(f'./results_{L}/VTD_params_{tf}_{L}_{p}_{dt}_{shots}.csv')): #! 2巡目からこっち VTCParamList = pd.read_csv(f'./results_{L}/VTD_params_{tf}_{L}_{p}_{dt}_{shots}.csv', index_col=0) VTCStepList = pd.read_csv(f'./results_{L}/VTD_results_{tf}_{L}_{p}_{dt}_{shots}.csv', index_col=0) temp = VTCParamList.iloc[-1] print(temp, "th time interval") U_v = AnsatzCircuit(temp, p) else: #! 最初はこっちに入る VTCParamList = pd.DataFrame(np.array(VTCParamList), index=np.array(TimeStep)) VTCStepList = pd.DataFrame(np.array(VTCStepList), index=np.array(TimeStep)) print("0 th time interval") print() U_v = QuantumCircuit(L) ts = VTCParamList.index #! 時間間隔 U_trot = TrotterEvolveCircuit(dt, p, QuantumCircuit(L)) #! Trotter分解のunitaryを作る print() print("start CMAES") print() res = CMAES(U_v, U_trot, init, p, backend, shots, filter) #! ここでプロセスを実行！！！！ print() print("res") pprint(res) #! 新しいループ結果を追加し、tsを更新 res = res.xbest # ! best solution evaluated print("res.xbest") pprint(res) VTCParamList.loc[ts[-1]+(dtp)] = np.array(res) VTCStepList.loc[ts[-1]+(dtp)] = np.array(SimulateAndReorder(init + AnsatzCircuit(res, p))) ts = VTCParamList.index # VTCParamList = pd.DataFrame(np.array(VTCParamList), index=np.array(TimeStep)) # VTCStepList = pd.DataFrame(np.array(VTCStepList), index=np.array(TimeStep)) #! csvファイルを更新 VTCParamList.to_csv(f'./results_{L}/VTD_params_{tf}_{L}_{p}_{dt}_{shots}.csv') VTCStepList.to_csv(f'./results_{L}/VTD_results_{tf}_{L}_{p}_{dt}_{shots}.csv') if (ts[-1] >= tf): return else: print("next step") VTC(tf, dt, p, init, backend, shots, filter) #! ここからQREM回路 qr = QuantumRegister(L) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # device_backend = FakeJakarta() # device_sim = AerSimulator.from_backend(device_backend) real_device = provider.get_backend('ibmq_jakarta') noise_model = NoiseModel.from_backend(real_device) device_sim = QasmSimulator(method='statevector', noise_model=noise_model) exact_sim = Aer.get_backend('qasm_simulator') # QasmSimulator(method='statevector') t_qc = transpile(meas_calibs) qobj = assemble(t_qc, shots=8192) # cal_results = real_device.run(qobj, shots=8192).result() cal_results = device_sim.run(qobj, shots=8192).result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') print("qrem done") # np.around(meas_fitter.cal_matrix, decimals=2) init = QuantumCircuit(L) # c = [str((1 + (-1)*(i+1)) // 2) for i in range(L)] c = ['1','1','0'] #! なぜinitial stateが110なの？？？？？？？もしかしてopen science prizeを意識??? #! けどループでこのプログラムが実行されるたびにここが\|110>だとおかしくないか？ for q in range(len(c)): if (c[q] == '1'): init.x(q) #! ここまでQREM回路 nt = int(np.ceil(tf / (dt p))) # f = open(f'./results_{L}/logging.txt', 'a') # sys.stdout = f #! tf: シミュレーションの(経過)時間 #! dt: trotter分解のステップ数 #! p: ansatzのステップ数 (論文中のL) # VTC(tf, dt, p, init, real_device, shots, meas_fitter.filter) #! mainの処理 print("vtc start!!!! \n\n\n") VTC(tf, dt, p, init, device_sim, shots, meas_fitter.filter) #! mainの処理 # f.close()
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools import pickle plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 100 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) print('Job ID', cal_job.job_id()) with open("jakarta_100step_2.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools import pickle plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 100 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) print('Job ID', cal_job.job_id()) with open("jakarta_100step.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("jakarta_100step.pkl", "rb") as f: job_list = pickle.load(f) jobs = job_list["jobs"] cal_job = job_list["cal_job"] cal_results = cal_job.result() print("retrieved cal_results") qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') results = [] mit_results = [] for i, job in enumerate(jobs): results.append(job.result()) mit_results.append( meas_fitter.filter.apply(job.result()) ) print("retrieved", i, "th results") # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) mit_fids = [] for mit_result in mit_results: mit_fid = state_tomo(mit_result, st_qcs) mit_fids.append(mit_fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(mit_fids), np.std(mit_fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 15 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) job_ids = \ ["624e8c85aacb9bd9c75f4da1", "624e8c894b515208aa7c6ae2", "624e8c8ba5d4eeac4977ccf3", "624e8c8ccfe45c1d4ae5a357", "624e8c8ef65d78307439029b", "624e8c9173968c1c2307b2c9", "624e8c93caa26524ecf199a9", "624e8c95aacb9b60c25f4da3"] # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) print('Job ID', cal_job.job_id()) jobs = [] for job_id in job_ids: jobs.append(backend.retrieve_job(job_id)) cal_job_id = "624e8c97a5d4ee882477ccf4" cal_job = backend.retrieve_job(cal_job_id) qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_results = cal_job.result() print("retrieved cal_results") meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for i, job in enumerate(jobs): mit_results.append( meas_fitter.filter.apply(job.result()) ) print("retrieved", i, "th results") # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools import pickle plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 100 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) print('Job ID', cal_job.job_id()) with open("jakarta_100step_2.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools import pickle plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 100 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) print('Job ID', cal_job.job_id()) with open("jakarta_100step.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("jakarta_100step.pkl", "rb") as f: job_list = pickle.load(f) jobs = job_list["jobs"] cal_job = job_list["cal_job"] cal_results = cal_job.result() print("retrieved cal_results") qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') results = [] mit_results = [] for i, job in enumerate(jobs): results.append(job.result()) mit_results.append( meas_fitter.filter.apply(job.result()) ) print("retrieved", i, "th results") # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) mit_fids = [] for mit_result in mit_results: mit_fid = state_tomo(mit_result, st_qcs) mit_fids.append(mit_fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(mit_fids), np.std(mit_fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 15 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) job_ids = \ ["624e8c85aacb9bd9c75f4da1", "624e8c894b515208aa7c6ae2", "624e8c8ba5d4eeac4977ccf3", "624e8c8ccfe45c1d4ae5a357", "624e8c8ef65d78307439029b", "624e8c9173968c1c2307b2c9", "624e8c93caa26524ecf199a9", "624e8c95aacb9b60c25f4da3"] # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) print('Job ID', cal_job.job_id()) jobs = [] for job_id in job_ids: jobs.append(backend.retrieve_job(job_id)) cal_job_id = "624e8c97a5d4ee882477ccf4" cal_job = backend.retrieve_job(cal_job_id) qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_results = cal_job.result() print("retrieved cal_results") meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for i, job in enumerate(jobs): mit_results.append( meas_fitter.filter.apply(job.result()) ) print("retrieved", i, "th results") # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt): qc = QuantumCircuit(2) qc.h(1) qc.cx(1,0) qc.h(1) qc.rz(- 2 * dt, 1) qc.rz(dt, 0) qc.h(1) qc.cx(1,0) qc.h(1) qc.rx(dt, [1]) qc.rz(-dt, [0,1]) qc.rx(-dt, [0,1]) qc = qc.reverse_bits() return qc.to_instruction() qc = QuantumCircuit(2) qc.h(1) qc.cx(1,0) qc.h(1) qc.rz(- 2 * np.pi / 6, 1) qc.rz(np.pi / 6, 0) qc.h(1) qc.cx(1,0) qc.h(1) qc.rx(np.pi / 6, [1]) qc.barrier() qc.rz(-np.pi / 6, [0,1]) qc.rx(-np.pi / 6, [0,1]) qc = qc.reverse_bits() qc.draw('mpl') # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # YOUR TROTTERIZATION GOES HERE -- FINISH (end of example) # The final time of the state evolution target_time = np.pi # Number of trotter steps trotter_steps = 12 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([3]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) shots = 8192 reps = 8 # WE USE A NOISELESS SIMULATION HERE backend = Aer.get_backend('qasm_simulator') # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [qr[1], qr[3], qr[5]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for job in jobs: fid = state_tomo(job.result(), st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) from qiskit.compiler import transpile t0_qc = transpile(qc, optimization_level=0, basis_gates=["sx","rz","cx"]) t0_qc.draw("mpl") t1_qc = transpile(qc, optimization_level=1, basis_gates=["sx","rz","cx"]) t1_qc.draw("mpl") t2_qc = transpile(qc, optimization_level=2, basis_gates=["sx","rz","cx"]) t2_qc.draw("mpl") t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx","rz","cx"]) t3_qc.draw("mpl") st_qcs = state_tomography_circuits(t2_qc, [qr[1], qr[3], qr[5]]) jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) fids = [] for job in jobs: fid = state_tomo(job.result(), st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) fids = [] for job in jobs: fid = state_tomo(job.result(), st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, ClassicalRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.compiler import transpile # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.h(1) qc.cx(1,0) qc.rx(dt, 1) qc.rz(- dt, 1) qc.rz(dt, 0) qc.cx(1,0) qc.h(1) qc.rx(dt, [1]) qc.rz(-dt, [0,1]) qc.rx(-dt, [0,1]) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 2 # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # YOUR TROTTERIZATION GOES HERE -- FINISH (end of example) target_time = np.pi shots = 8192 reps = 1 # WE USE A NOISELESS SIMULATION HERE backend = Aer.get_backend('qasm_simulator') counts_01 = [] counts_10 = [] for trotter_steps in range(0, 16, 1): print("number of trotter steps: ", trotter_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(2) cr = ClassicalRegister(2) qc = QuantumCircuit(qr, cr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) # init state \|10> (= \|110>) qc.x(0) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[0], qr[1]]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / trotter_steps}) if trotter_steps > 0 else qc t0_qc = transpile(qc, optimization_level=3, basis_gates=["sx","rz","cx"]) t0_qc = t0_qc.reverse_bits() t0_qc.measure(qr, cr) print("circuit depth: ", t0_qc.depth()) job = execute(t0_qc, backend=backend, shots=shots, optimization_level=0) print("pribability distribution: ", job.result().get_counts()) counts_01.append(job.result().get_counts().get("01", 0)) counts_10.append(job.result().get_counts().get("10", 0)) print() plt.plot(range(0,16), counts_10) plt.xlabel("trotter steps") plt.ylabel("shot counts of 10") plt.title("counts of \|10>") plt.plot(range(0,16), counts_01) plt.xlabel("trotter steps") plt.ylabel("shot counts of 01") plt.title("counts of \|01>") t0_qc.draw("mpl")
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, ClassicalRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.compiler import transpile # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.h(1) qc.cx(1,0) qc.rx(dt, 1) qc.rz(- dt, 1) qc.rz(dt, 0) qc.cx(1,0) qc.h(1) qc.rx(dt, [1]) qc.rz(-dt, [0,1]) qc.rx(-dt, [0,1]) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # YOUR TROTTERIZATION GOES HERE -- FINISH (end of example) # The final time of the state evolution target_time = np.pi # Number of trotter steps trotter_steps = 4 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(3) cr = ClassicalRegister(3) qc = QuantumCircuit(qr, cr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) # init state \|10> (= \|110>) qc.x(1) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[1], qr[2]]) qc.cx(qr[1], qr[0]) qc.cx(qr[2], qr[1]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / trotter_steps}) qc.measure(qr, cr) t0_qc = transpile(qc, optimization_level=0, basis_gates=["sx","rz","cx"]) # t0_qc.draw("mpl") t0_qc = t0_qc.reverse_bits() # t0_qc.draw("mpl") shots = 8192 reps = 1 # WE USE A NOISELESS SIMULATION HERE backend = Aer.get_backend('qasm_simulator') jobs = [] for _ in range(reps): # execute job = execute(t0_qc, backend=backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) counts_110 = [] # counts_10 = [] for trotter_steps in range(1, 15, 1): print("number of trotter steps: ", trotter_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(3) cr = ClassicalRegister(3) qc = QuantumCircuit(qr, cr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) # init state \|10> (= \|110>) qc.x(1) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(0, trotter_steps + 1): qc.append(Trot_gate, [qr[1], qr[2]]) qc.cx(qr[1], qr[0]) qc.cx(qr[2], qr[1]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / trotter_steps}) t0_qc = transpile(qc, optimization_level=0, basis_gates=["sx","rz","cx"]) t0_qc = t0_qc.reverse_bits() t0_qc.measure(qr, cr) print("circuit depth: ", t0_qc.depth()) job = execute(t0_qc, backend=backend, shots=shots, optimization_level=0) print("pribability distribution: ", job.result().get_counts()) counts_110.append(job.result().get_counts().get("110", 0)) # counts_10.append(job.result().get_counts().get("10", 0)) print() plt.plot(range(1,15), counts_110) plt.xlabel("trotter steps") plt.ylabel("shot counts of 110") plt.title("counts of \|110>") plt.plot(range(1,15), counts_01) plt.xlabel("trotter steps") plt.ylabel("shot counts of 01") plt.title("counts of \|01>")
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt): qc = QuantumCircuit(2) qc.h(1) qc.cx(1,0) qc.h(1) qc.rz(- 2 * dt, 1) qc.rz(dt, 0) qc.h(1) qc.cx(1,0) qc.h(1) qc.rx(dt, [1]) qc.rz(-dt, [0,1]) qc.rx(-dt, [0,1]) return qc.to_instruction() qc = QuantumCircuit(2) qc.h(1) qc.cx(1,0) qc.h(1) qc.rz(- 2 * np.pi / 6, 1) qc.rz(np.pi / 6, 0) qc.h(1) qc.cx(1,0) qc.h(1) qc.rx(np.pi / 6, [1]) qc.barrier() qc.rz(-np.pi / 6, [0,1]) qc.rx(-np.pi / 6, [0,1]) qc.draw('mpl') # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # YOUR TROTTERIZATION GOES HERE -- FINISH (end of example) # The final time of the state evolution target_time = np.pi # Number of trotter steps trotter_steps = 1 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([3]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) shots = 8192 reps = 8 # WE USE A NOISELESS SIMULATION HERE backend = Aer.get_backend('qasm_simulator') # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [qr[1], qr[3], qr[5]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for job in jobs: fid = state_tomo(job.result(), st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) from qiskit.compiler import transpile t0_qc = transpile(qc, optimization_level=0, basis_gates=["sx","rz","cx"]) t0_qc.draw("mpl") t1_qc = transpile(qc, optimization_level=1, basis_gates=["sx","rz","cx"]) t1_qc.draw("mpl") t2_qc = transpile(qc, optimization_level=2, basis_gates=["sx","rz","cx"]) t2_qc.draw("mpl") t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx","rz","cx"]) t3_qc.draw("mpl") st_qcs = state_tomography_circuits(t2_qc, [qr[1], qr[3], qr[5]]) jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) fids = [] for job in jobs: fid = state_tomo(job.result(), st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) fids = [] for job in jobs: fid = state_tomo(job.result(), st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, ClassicalRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.compiler import transpile # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.h(1) qc.cx(1,0) qc.rx(dt, 1) qc.rz(- dt, 1) qc.rz(dt, 0) qc.cx(1,0) qc.h(1) qc.rx(dt, [1]) qc.rz(-dt, [0,1]) qc.rx(-dt, [0,1]) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 2 # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # YOUR TROTTERIZATION GOES HERE -- FINISH (end of example) target_time = np.pi shots = 8192 reps = 1 # WE USE A NOISELESS SIMULATION HERE backend = Aer.get_backend('qasm_simulator') counts_01 = [] counts_10 = [] for trotter_steps in range(0, 16, 1): print("number of trotter steps: ", trotter_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(2) cr = ClassicalRegister(2) qc = QuantumCircuit(qr, cr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) # init state \|10> (= \|110>) qc.x(0) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[0], qr[1]]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / trotter_steps}) if trotter_steps > 0 else qc t0_qc = transpile(qc, optimization_level=3, basis_gates=["sx","rz","cx"]) t0_qc = t0_qc.reverse_bits() t0_qc.measure(qr, cr) print("circuit depth: ", t0_qc.depth()) job = execute(t0_qc, backend=backend, shots=shots, optimization_level=0) print("pribability distribution: ", job.result().get_counts()) counts_01.append(job.result().get_counts().get("01", 0)) counts_10.append(job.result().get_counts().get("10", 0)) print() plt.plot(range(0,16), counts_10) plt.xlabel("trotter steps") plt.ylabel("shot counts of 10") plt.title("counts of \|10>") plt.plot(range(0,16), counts_01) plt.xlabel("trotter steps") plt.ylabel("shot counts of 01") plt.title("counts of \|01>") t0_qc.draw("mpl")
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, ClassicalRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.compiler import transpile # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt): qc = QuantumCircuit(2) qc.h(1) qc.cx(1,0) qc.h(1) qc.rz(- 2 * dt, 1) qc.rz(dt, 0) qc.h(1) qc.cx(1,0) qc.h(1) qc.rx(dt, [1]) qc.rz(-dt, [0,1]) qc.rx(-dt, [0,1]) return qc.to_instruction() qc = QuantumCircuit(2) qc.h(1) qc.cx(1,0) qc.h(1) qc.rz(- 2 * np.pi / 6, 1) qc.rz(np.pi / 6, 0) qc.h(1) qc.cx(1,0) qc.h(1) qc.rx(np.pi / 6, [1]) qc.barrier() qc.rz(-np.pi / 6, [0,1]) qc.rx(-np.pi / 6, [0,1]) qc.draw('mpl') # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 2 # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # YOUR TROTTERIZATION GOES HERE -- FINISH (end of example) # The final time of the state evolution target_time = np.pi # Number of trotter steps trotter_steps = 4 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(2) cr = ClassicalRegister(2) qc = QuantumCircuit(qr, cr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) # init state \|10> (= \|110>) qc.x(1) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[0], qr[1]]) # qc.cx(qr[3], qr[1]) # qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / trotter_steps}) qc.measure(qr, cr) t0_qc = transpile(qc, optimization_level=0, basis_gates=["sx","rz","cx"]) # t0_qc.draw("mpl") t0_qc = t0_qc.reverse_bits() # t0_qc.draw("mpl") shots = 8192 reps = 1 # WE USE A NOISELESS SIMULATION HERE backend = Aer.get_backend('qasm_simulator') jobs = [] for _ in range(reps): # execute job = execute(t0_qc, backend=backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) counts_01 = [] counts_10 = [] for trotter_steps in range(1, 15, 1): print("number of trotter steps: ", trotter_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(2) cr = ClassicalRegister(2) qc = QuantumCircuit(qr, cr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) # init state \|10> (= \|110>) qc.x(1) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[0], qr[1]]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / trotter_steps}) qc.measure(qr, cr) t0_qc = transpile(qc, optimization_level=0, basis_gates=["sx","rz","cx"]) t0_qc = t0_qc.reverse_bits() print("circuit depth: ", t0_qc.depth()) job = execute(t0_qc, backend=backend, shots=shots, optimization_level=0) print("pribability distribution: ", job.result().get_counts()) counts_01.append(job.result().get_counts().get("01", 0)) counts_10.append(job.result().get_counts().get("10", 0)) print() plt.plot(range(1,15), counts_10) plt.xlabel("trotter steps") plt.ylabel("shot counts of 10") plt.title("counts of \|10>") plt.plot(range(1,15), counts_01) plt.xlabel("trotter steps") plt.ylabel("shot counts of 01") plt.title("counts of \|01>")
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 15 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([2]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[1], qr[2]]) qc.cx(qr[1], qr[0]) qc.cx(qr[2], qr[1]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[0], qr[1], qr[2]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibm_lagos") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 15 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(5) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([2]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[1], qr[2]]) qc.cx(qr[1], qr[0]) qc.cx(qr[2], qr[1]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[0], qr[1], qr[2]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_quito") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 15 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([2]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[1], qr[2]]) qc.cx(qr[1], qr[0]) qc.cx(qr[2], qr[1]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[0], qr[1], qr[2]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibm_lagos") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 15 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(5) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([2]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[1], qr[2]]) qc.cx(qr[1], qr[0]) qc.cx(qr[2], qr[1]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[0], qr[1], qr[2]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_quito") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) # from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 15 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates st_qcs[13].draw("mpl") # Pauli Twirling # TODO: 一度挙動を調べる def pauli_twirling(circ: str) -> QuantumCircuit: """ そのまま使う: 修正は後回し """ #! qasm ベタ書き def apply_pauli(num: int, qb: int) -> str: if (num == 0): return f'id q[{qb}];\n' elif (num == 1): return f'x q[{qb}];\n' elif (num == 2): return f'y q[{qb}];\n' else: return f'z q[{qb}];\n' paulis = [(i,j) for i in range(0,4) for j in range(0,4)] paulis.remove((0,0)) paulis_map = [(0, 1), (3, 2), (3, 3), (1, 1), (1, 0), (2, 3), (2, 2), (2, 1), (2, 0), (1, 3), (1, 2), (3, 0), (3, 1), (0, 2), (0, 3)] new_circ = '' ops = circ.qasm().splitlines(True) #! 生のqasmコードを持ってきてる: オペレータに分解 for op in ops: if (op[:2] == 'cx'): # can add for cz, etc. num = random.randrange(len(paulis)) #! permute paulis qbs = re.findall('q\[(.)\]', op) new_circ += apply_pauli(paulis[num][0], qbs[0]) new_circ += apply_pauli(paulis[num][1], qbs[1]) new_circ += op new_circ += apply_pauli(paulis_map[num][0], qbs[0]) new_circ += apply_pauli(paulis_map[num][1], qbs[1]) else: new_circ += op return qiskit.circuit.QuantumCircuit.from_qasm_str(new_circ) # ZNE # 3種類の実行方法 # 1. state tomography回路全体をzne # 2. state tomography前の回路をzne # 3. 2-qubitの状態だけzne # 今回は1を実装する def zne_wrapper(qcs, scale_factors = [1.0, 2.0, 3.0]): """ """ folded_qcs = [] #! ZNE用の回路 for qc in qcs: folded_qcs.append([mitiq.zne.scaling.fold_gates_at_random(qc, scale) for scale in scale_factors]) #! ここでmitiqを使用 folded_qcs = list(itertools.chain(folded_qcs)) #! folded_qcsを平坦化 folded_qcs = [pauli_twirling(circ) for circ in folded_qcs] #! 後からPauli Twirlingを施す! return folded_qcs # subspace expansion # TODO: 実装はとりあえず後回し def se_wrapper(qcs): """ """ folded_qcs = [] for qc in qcs: pass return folded_qcs from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') def make_basis3(): n = 3 basis = [] for q0 in range(4): for q1 in range(4): for q2 in range(4): basis.append([q0, q1, q2]) return basis def make_basis(n): basis = np.zeros((1 << n, n), dtype="int") for i in range(4): for j in range(4): for k in range(4): for in range(4): return basis def make_state_tomography_circuits(qc, basis): basis = make_basis3() st_qcs = [] for v in basis: mqc = QuantumCircuit(3) for i in v: if i == 0: continue elif i == 1: mqc.measure() elif i == 2: ret = np.kron(ret, Y) elif i == 3: ret = np.kron(ret, Z) else: raise Exception st_qcs.append(qc.compose(mqc, [0,1,2])) def measurement_basis(v): I = np.array([[1,0],[0,1]], dtype="complex") X = np.array([[0,1],[1,0]], dtype="complex") Y = np.array([[0,-1j],[1j,0]], dtype="complex") Z = np.array([[1,0],[0,-1]], dtype="complex") ret = I for i in v: if i == 0: ret = np.kron(ret, I) elif i == 1: ret = np.kron(ret, X) elif i == 2: ret = np.kron(ret, Y) elif i == 3: ret = np.kron(ret, Z) else: raise Exception return ret def state_tomography(n, expvals, vs): rho = np.zeros((1 << n, 1 << n), dtype="complex") for i, v in enumerate(vs): rho += expvals[i] measurement_basis(v) return rho / (1 << n) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(expvals, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid stf = StateTomographyFitter(job.result(), st_qcs) stf._data from IPython.core.debugger import Pdb; Pdb().set_trace() data, basis_matrix, weights = stf._fitter_data(True, 0.5) next(iter(stf._data)) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for job in jobs: fid = state_tomo(job.result(), st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2 * dt, 0) qc.rz(2 * dt, 1) qc.h(1) qc.cx(1, 0) qc.rz(-2 * dt, 0) qc.rx(-2 * dt, 1) qc.rz(2 * dt, 1) qc.cx(1, 0) qc.h(1) qc.rz(2 * dt, 0) return qc.to_instruction() if to_instruction else qc dt = Parameter('(-2t/n)') trotter_gate(dt, to_instruction=False).draw("mpl") dt = Parameter('2t/n') mdt = Parameter('-2t/n') qc = QuantumCircuit(2) qc.rx(dt, 0) qc.rz(dt, 1) qc.h(1) qc.cx(1, 0) qc.rz(mdt, 0) qc.rx(mdt, 1) qc.rz(dt, 1) qc.cx(1, 0) qc.h(1) qc.rz(dt, 0) qc.draw("mpl") dt = Parameter('2t/n') mdt = Parameter('-2t/n') qc = QuantumCircuit(2) qc.h(1) qc.cx(1, 0) qc.rz(mdt, 0) qc.rx(mdt, 1) qc.rz(dt, 1) qc.cx(1, 0) qc.h(1) qc.rx(dt, 1) qc.draw("mpl") trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") def make_initial_state(qc, initial_state): """ logical qubit index little endian """ for i, state in enumerate(initial_state): if state == "1": qc.x(i) qc = QuantumCircuit(3) make_initial_state(qc, "110") qc.draw("mpl") def subspace_encoder(qc, targets): """ naive method, can be optimized for init state \|110> little endian """ n = qc.num_qubits qc.cx(targets[2],targets[1]) qc.cx(targets[1],targets[0]) def subspace_encoder_init110(qc, targets): """ optimized encoder for init state \|110> endian: \|q_0, q_1, q_2> (little endian) encode \|110> to \|0>\|10> """ n = qc.num_qubits qc.x(targets[0]) def subspace_decoder(qc, targets): """ naive method little endian """ n = qc.num_qubits qc.cx(targets[1], targets[0]) qc.cx(targets[2], targets[1]) qc = QuantumCircuit(3) make_initial_state(qc, "110") subspace_encoder_init110(qc, targets=[0,1,2]) qc.draw("mpl") def trotterize(qc, trot_gate, num_steps, targets): for _ in range(num_steps): qc.append(trot_gate, qargs = targets) qc = QuantumCircuit(3) make_initial_state(qc, "110") subspace_encoder_init110(qc, targets=[0,1,2]) qc.barrier() trotterize(qc, trotter_gate(np.pi / 6), 1, targets=[1, 2]) qc = transpile(qc, optimization_level = 3, basis_gates=["sx", "rz", "cx"]) qc.draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] st_qcs_list = [] # Number of trotter steps max_trotter_step = 50 ### CAN BE >= 4 trotter_steps = list(range(1, max_trotter_step + 1, 3)) for num_steps in trotter_steps: print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) st_qcs_list.append(t3_st_qcs) st_qcs_list[-1][-1].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") jobs = [] shots = 1 << 13 # Number of trotter steps for i, num_steps in enumerate(trotter_steps): print("trotter step: ", num_steps) # execute: reps = 1 job = execute(st_qcs_list[i], backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) print() # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') results = [] for job in jobs: results.append( job.result() ) mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) print(len(results), len(mit_results)) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition raw_fids = [] for result in results: fid = state_tomo(result, st_qcs) raw_fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) plt.clf() plt.style.use('ggplot') plt.figure(dpi=200) plt.title("state fidelity from Trotter step 1 to "+str(trotter_steps)) plt.plot(trotter_steps, raw_fids, label="raw fidelity") plt.plot(trotter_steps, fids, label="fidelity after QREM") plt.xlabel("number of trotter steps") plt.ylabel("fidelity") plt.grid(linestyle='dotted') for step, fid in zip(trotter_steps, raw_fids): print(step, fid) for step, fid in zip(trotter_steps, fids): print(step, fid)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	# Import general libraries (needed for functions) import numpy as np import time # Import Qiskit classes import qiskit from qiskit import QuantumRegister, QuantumCircuit, ClassicalRegister, Aer from qiskit.providers.aer import noise from qiskit.tools.visualization import plot_histogram # Import measurement calibration functions from qiskit.ignis.mitigation.measurement import (complete_meas_cal, tensored_meas_cal, CompleteMeasFitter, TensoredMeasFitter) # Generate the calibration circuits qr = qiskit.QuantumRegister(3) qubit_list = [0,1,2] meas_calibs, state_labels = complete_meas_cal(qubit_list=qubit_list, qr=qr, circlabel='mcal') state_labels # Execute the calibration circuits without noise backend = qiskit.Aer.get_backend('qasm_simulator') job = qiskit.execute(meas_calibs, backend=backend, shots=1000) cal_results = job.result() # The calibration matrix without noise is the identity matrix meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') print(meas_fitter.cal_matrix) # Generate a noise model for the 5 qubits noise_model = noise.NoiseModel() for qi in range(1): read_err = noise.errors.readout_error.ReadoutError([[0.9, 0.1],[0.25,0.75]]) noise_model.add_readout_error(read_err, [qi]) # Execute the calibration circuits backend = qiskit.Aer.get_backend('qasm_simulator') job = qiskit.execute(meas_calibs, backend=backend, shots=1000, noise_model=noise_model) cal_results = job.result() # Calculate the calibration matrix with the noise model meas_fitter = CompleteMeasFitter(cal_results, state_labels, qubit_list=qubit_list, circlabel='mcal') print(meas_fitter.cal_matrix) # Plot the calibration matrix meas_fitter.plot_calibration() # What is the measurement fidelity? print("Average Measurement Fidelity: %f" % meas_fitter.readout_fidelity()) # What is the measurement fidelity of Q0? print("Average Measurement Fidelity of Q0: %f" % meas_fitter.readout_fidelity( label_list = [['000','001','010','011'],['100','101','110','111']])) # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity from qiskit.opflow import Zero, One, I, X, Y, Z # Make a 3Q GHZ state cr = ClassicalRegister(3) qc = QuantumCircuit(qr) qc.x([0,1]) # ghz.h(qr[0]) # ghz.cx(qr[0], qr[1]) # ghz.cx(qr[1], qr[2]) # ghz.measure(qr[0],cr[0]) # ghz.measure(qr[1],cr[1]) # ghz.measure(qr[2],cr[2]) st_qcs = state_tomography_circuits(qc, [0,1,2]) st_qcs[-1].draw("mpl") job = qiskit.execute(st_qcs, backend=backend, shots=5000, noise_model=noise_model) results = job.result() # Results without mitigation raw_counts = results.get_counts() # Get the filter object meas_filter = meas_fitter.filter # Results with mitigation mitigated_results = meas_filter.apply(results) mitigated_counts = mitigated_results.get_counts() from qiskit.tools.visualization import * plot_histogram([raw_counts[-1], mitigated_counts[-1]], legend=['raw', 'mitigated']) def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid state_tomo(mitigated_results, st_qcs) # Make a 3Q GHZ state cr = ClassicalRegister(3) qc = QuantumCircuit(qr) qc.x([0,1]) # ghz.h(qr[0]) # ghz.cx(qr[0], qr[1]) # ghz.cx(qr[1], qr[2]) # ghz.measure(qr[0],cr[0]) # ghz.measure(qr[1],cr[1]) # ghz.measure(qr[2],cr[2]) st_qcs = state_tomography_circuits(qc, [0,1,2][::-1]) job = qiskit.execute(st_qcs, backend=backend, shots=5000, noise_model=noise_model) results = job.result() # Results without mitigation raw_counts = results.get_counts() # Get the filter object meas_filter = meas_fitter.filter # Results with mitigation mitigated_results = meas_filter.apply(results) mitigated_counts = mitigated_results.get_counts() from qiskit.tools.visualization import * plot_histogram([raw_counts[-1], mitigated_counts[-1]], legend=['raw', 'mitigated']) state_tomo(mitigated_results, st_qcs) state_tomo(results, st_qcs)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import re import numpy as np import matplotlib.pyplot as plt import itertools import random import pickle plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 100 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits # qr = QuantumRegister(7) qc = QuantumCircuit(3) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([1,0]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) qc.x([1]) # encoding # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [1, 0]) qc.cx(1, 2) qc.cx(0, 1) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) # circuit optimization t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [2, 1, 0]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates # Pauli Twirling def pauli_twirling(circ: str) -> QuantumCircuit: """ そのまま使う: 修正は後回し """ #! qasm ベタ書き def apply_pauli(num: int, qb: int) -> str: if (num == 0): return f'id q[{qb}];\n' elif (num == 1): return f'x q[{qb}];\n' elif (num == 2): return f'y q[{qb}];\n' else: return f'z q[{qb}];\n' paulis = [(i,j) for i in range(0,4) for j in range(0,4)] paulis.remove((0,0)) paulis_map = [(0, 1), (3, 2), (3, 3), (1, 1), (1, 0), (2, 3), (2, 2), (2, 1), (2, 0), (1, 3), (1, 2), (3, 0), (3, 1), (0, 2), (0, 3)] new_circ = '' ops = circ.qasm().splitlines(True) #! 生のqasmコードを持ってきてる: オペレータに分解 for op in ops: if (op[:2] == 'cx'): # can add for cz, etc. num = random.randrange(len(paulis)) #! permute paulis qbs = re.findall('q\[(.)\]', op) new_circ += apply_pauli(paulis[num][0], qbs[0]) new_circ += apply_pauli(paulis[num][1], qbs[1]) new_circ += op new_circ += apply_pauli(paulis_map[num][0], qbs[0]) new_circ += apply_pauli(paulis_map[num][1], qbs[1]) else: new_circ += op return QuantumCircuit.from_qasm_str(new_circ) def zne_wrapper(qcs, scale_factors = [1.0, 2.0, 3.0]): """ """ folded_qcs = [] #! ZNE用の回路 for qc in qcs: folded_qcs.append([mitiq.zne.scaling.fold_gates_at_random(qc, scale) for scale in scale_factors]) #! ここでmitiqを使用 folded_qcs = list(itertools.chain(*folded_qcs)) #! folded_qcsを平坦化 folded_qcs = [pauli_twirling(circ) for circ in folded_qcs] #! 後からPauli Twirlingを施す! return folded_qcs zne_qcs = zne_wrapper(st_qcs) print("number of circuits: ", len(zne_qcs)) zne_qcs[-3].draw("mpl") zne_qcs_jakarta = transpile(zne_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"], initial_layout=[5,3,1]) zne_qcs_jakarta = transpile(zne_qcs_jakarta, optimization_level=3, basis_gates=["sx", "cx", "rz"]) from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) print('Job ID', cal_job.job_id()) with open("jakarta_100step.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 15 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # backend = provider.get_backend("ibmq_jakarta") jobs = [] st_qcs_list = [] shots = 1 << 13 # Number of trotter steps trotter_steps = 8 ### CAN BE >= 4 for num_steps in range(1, trotter_steps + 1, 1): print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(num_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/num_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) st_qcs_list.append(st_qcs) # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) print() # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout=[5,3,1]) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') results = [] for job in jobs: results.append( job.result() ) mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) len(results), len(mit_results) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition raw_fids = [] for result in results: fid = state_tomo(result, st_qcs) raw_fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) plt.clf() plt.title("fidelity with QREM") plt.plot(range(1, trotter_steps + 1, 1), raw_fids) plt.plot(range(1, trotter_steps + 1, 1), fids) plt.xlabel("number of trotter steps") plt.ylabel("fidelity") for i, fid in enumerate(raw_fids): print(i+1, fid) for i, fid in enumerate(fids): print(i+1, fid) st_qcs_list[-1][-1].draw("mpl") st_qcs_list[-2][-1].draw("mpl")
https://github.com/BOBO1997/osp_solutions	BOBO1997	import re import numpy as np import matplotlib.pyplot as plt import itertools import random import pickle plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 100 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits # qr = QuantumRegister(7) qc = QuantumCircuit(3) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([1,0]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) qc.x([1]) # encoding # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [1, 0]) qc.cx(1, 2) qc.cx(0, 1) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) # circuit optimization t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [2, 1, 0]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates def zne_wrapper(qcs, scale_factors = [1.0, 2.0, 3.0]): """ """ folded_qcs = [] #! ZNE用の回路 for qc in qcs: folded_qcs.append([mitiq.zne.scaling.fold_gates_at_random(qc, scale) for scale in scale_factors]) #! ここでmitiqを使用 folded_qcs = list(itertools.chain(*folded_qcs)) #! folded_qcsを平坦化 return folded_qcs zne_qcs = zne_wrapper(st_qcs) print("number of circuits: ", len(zne_qcs)) zne_qcs[-3].draw("mpl") zne_qcs_jakarta = transpile(zne_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"], initial_layout=[5,3,1]) zne_qcs_jakarta = transpile(zne_qcs_jakarta, optimization_level=3, basis_gates=["sx", "cx", "rz"]) zne_qcs_jakarta[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) # from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 15 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates st_qcs[13].draw("mpl") # Pauli Twirling # TODO: 一度挙動を調べる def pauli_twirling(circ: str) -> QuantumCircuit: """ そのまま使う: 修正は後回し """ #! qasm ベタ書き def apply_pauli(num: int, qb: int) -> str: if (num == 0): return f'id q[{qb}];\n' elif (num == 1): return f'x q[{qb}];\n' elif (num == 2): return f'y q[{qb}];\n' else: return f'z q[{qb}];\n' paulis = [(i,j) for i in range(0,4) for j in range(0,4)] paulis.remove((0,0)) paulis_map = [(0, 1), (3, 2), (3, 3), (1, 1), (1, 0), (2, 3), (2, 2), (2, 1), (2, 0), (1, 3), (1, 2), (3, 0), (3, 1), (0, 2), (0, 3)] new_circ = '' ops = circ.qasm().splitlines(True) #! 生のqasmコードを持ってきてる: オペレータに分解 for op in ops: if (op[:2] == 'cx'): # can add for cz, etc. num = random.randrange(len(paulis)) #! permute paulis qbs = re.findall('q\[(.)\]', op) new_circ += apply_pauli(paulis[num][0], qbs[0]) new_circ += apply_pauli(paulis[num][1], qbs[1]) new_circ += op new_circ += apply_pauli(paulis_map[num][0], qbs[0]) new_circ += apply_pauli(paulis_map[num][1], qbs[1]) else: new_circ += op return qiskit.circuit.QuantumCircuit.from_qasm_str(new_circ) # ZNE # 3種類の実行方法 # 1. state tomography回路全体をzne # 2. state tomography前の回路をzne # 3. 2-qubitの状態だけzne # 今回は1を実装する def zne_wrapper(qcs, scale_factors = [1.0, 2.0, 3.0]): """ """ folded_qcs = [] #! ZNE用の回路 for qc in qcs: folded_qcs.append([mitiq.zne.scaling.fold_gates_at_random(qc, scale) for scale in scale_factors]) #! ここでmitiqを使用 folded_qcs = list(itertools.chain(folded_qcs)) #! folded_qcsを平坦化 folded_qcs = [pauli_twirling(circ) for circ in folded_qcs] #! 後からPauli Twirlingを施す! return folded_qcs # subspace expansion # TODO: 実装はとりあえず後回し def se_wrapper(qcs): """ """ folded_qcs = [] for qc in qcs: pass return folded_qcs from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') def make_basis(n): basis = np.zeros((1 << n, n), dtype="int") return basis def measurement_basis(v): I = np.array([[1,0],[0,1]], dtype="complex") X = np.array([[0,1],[1,0]], dtype="complex") Y = np.array([[0,-1j],[1j,0]], dtype="complex") Z = np.array([[1,0],[0,-1]], dtype="complex") ret = I for i in v: if i == 0: ret = np.kron(ret, I) elif i == 1: ret = np.kron(ret, X) elif i == 2: ret = np.kron(ret, Y) elif i == 3: ret = np.kron(ret, Z) else: raise Exception return ret def state_tomography(n, expvals, vs): rho = np.zeros((1 << n, 1 << n), dtype="complex") for i, v in enumerate(vs): rho += expvals[i] measurement_basis(v) return rho / (1 << n) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(expvals, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid stf = StateTomographyFitter(job.result(), st_qcs) stf._data from IPython.core.debugger import Pdb; Pdb().set_trace() data, basis_matrix, weights = stf._fitter_data(True, 0.5) next(iter(stf._data)) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for job in jobs: fid = state_tomo(job.result(), st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2 * dt, 0) qc.rz(2 * dt, 1) qc.h(1) qc.cx(1, 0) qc.rz(-2 * dt, 0) qc.rx(-2 * dt, 1) qc.rz(2 * dt, 1) qc.cx(1, 0) qc.h(1) qc.rz(2 * dt, 0) return qc.to_instruction() if to_instruction else qc dt = Parameter('(-2t/n)') trotter_gate(dt, to_instruction=False).draw("mpl") dt = Parameter('2t/n') mdt = Parameter('-2t/n') qc = QuantumCircuit(2) qc.rx(dt, 0) qc.rz(dt, 1) qc.h(1) qc.cx(1, 0) qc.rz(mdt, 0) qc.rx(mdt, 1) qc.rz(dt, 1) qc.cx(1, 0) qc.h(1) qc.rz(dt, 0) qc.draw("mpl") dt = Parameter('2t/n') mdt = Parameter('-2t/n') qc = QuantumCircuit(2) qc.h(1) qc.cx(1, 0) qc.rz(mdt, 0) qc.rx(mdt, 1) qc.rz(dt, 1) qc.cx(1, 0) qc.h(1) qc.rx(dt, 1) qc.draw("mpl") trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") def make_initial_state(qc, initial_state): """ logical qubit index little endian """ for i, state in enumerate(initial_state): if state == "1": qc.x(i) qc = QuantumCircuit(3) make_initial_state(qc, "110") qc.draw("mpl") def subspace_encoder(qc, targets): """ naive method, can be optimized for init state \|110> little endian """ n = qc.num_qubits qc.cx(targets[2],targets[1]) qc.cx(targets[1],targets[0]) def subspace_encoder_init110(qc, targets): """ optimized encoder for init state \|110> endian: \|q_0, q_1, q_2> (little endian) encode \|110> to \|0>\|10> """ n = qc.num_qubits qc.x(targets[0]) def subspace_decoder(qc, targets): """ naive method little endian """ n = qc.num_qubits qc.cx(targets[1], targets[0]) qc.cx(targets[2], targets[1]) qc = QuantumCircuit(3) make_initial_state(qc, "110") subspace_encoder_init110(qc, targets=[0,1,2]) qc.draw("mpl") def trotterize(qc, trot_gate, num_steps, targets): for _ in range(num_steps): qc.append(trot_gate, qargs = targets) qc = QuantumCircuit(3) make_initial_state(qc, "110") subspace_encoder_init110(qc, targets=[0,1,2]) qc.barrier() trotterize(qc, trotter_gate(np.pi / 6), 1, targets=[1, 2]) qc = transpile(qc, optimization_level = 3, basis_gates=["sx", "rz", "cx"]) qc.draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] st_qcs_list = [] # Number of trotter steps max_trotter_step = 50 ### CAN BE >= 4 trotter_steps = list(range(1, max_trotter_step + 1, 3)) for num_steps in trotter_steps: print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) st_qcs_list.append(t3_st_qcs) st_qcs_list[-1][-1].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") jobs = [] shots = 1 << 13 # Number of trotter steps for i, num_steps in enumerate(trotter_steps): print("trotter step: ", num_steps) # execute: reps = 1 job = execute(st_qcs_list[i], backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) print() # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') results = [] for job in jobs: results.append( job.result() ) mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) print(len(results), len(mit_results)) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition raw_fids = [] for result in results: fid = state_tomo(result, st_qcs) raw_fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) plt.clf() plt.style.use('ggplot') plt.figure(dpi=200) plt.title("state fidelity from Trotter step 1 to "+str(trotter_steps)) plt.plot(trotter_steps, raw_fids, label="raw fidelity") plt.plot(trotter_steps, fids, label="fidelity after QREM") plt.xlabel("number of trotter steps") plt.ylabel("fidelity") plt.grid(linestyle='dotted') for step, fid in zip(trotter_steps, raw_fids): print(step, fid) for step, fid in zip(trotter_steps, fids): print(step, fid)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	# Import general libraries (needed for functions) import numpy as np import time # Import Qiskit classes import qiskit from qiskit import QuantumRegister, QuantumCircuit, ClassicalRegister, Aer from qiskit.providers.aer import noise from qiskit.tools.visualization import plot_histogram # Import measurement calibration functions from qiskit.ignis.mitigation.measurement import (complete_meas_cal, tensored_meas_cal, CompleteMeasFitter, TensoredMeasFitter) # Generate the calibration circuits qr = qiskit.QuantumRegister(3) qubit_list = [0,1,2] meas_calibs, state_labels = complete_meas_cal(qubit_list=qubit_list, qr=qr, circlabel='mcal') state_labels # Execute the calibration circuits without noise backend = qiskit.Aer.get_backend('qasm_simulator') job = qiskit.execute(meas_calibs, backend=backend, shots=1000) cal_results = job.result() # The calibration matrix without noise is the identity matrix meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') print(meas_fitter.cal_matrix) # Generate a noise model for the 5 qubits noise_model = noise.NoiseModel() for qi in range(1): read_err = noise.errors.readout_error.ReadoutError([[0.9, 0.1],[0.25,0.75]]) noise_model.add_readout_error(read_err, [qi]) # Execute the calibration circuits backend = qiskit.Aer.get_backend('qasm_simulator') job = qiskit.execute(meas_calibs, backend=backend, shots=1000, noise_model=noise_model) cal_results = job.result() # Calculate the calibration matrix with the noise model meas_fitter = CompleteMeasFitter(cal_results, state_labels, qubit_list=qubit_list, circlabel='mcal') print(meas_fitter.cal_matrix) # Plot the calibration matrix meas_fitter.plot_calibration() # What is the measurement fidelity? print("Average Measurement Fidelity: %f" % meas_fitter.readout_fidelity()) # What is the measurement fidelity of Q0? print("Average Measurement Fidelity of Q0: %f" % meas_fitter.readout_fidelity( label_list = [['000','001','010','011'],['100','101','110','111']])) # Make a 3Q GHZ state cr = ClassicalRegister(3) ghz = QuantumCircuit(qr, cr) ghz.h(qr[0]) ghz.cx(qr[0], qr[1]) ghz.cx(qr[1], qr[2]) ghz.measure(qr[0],cr[0]) ghz.measure(qr[1],cr[1]) ghz.measure(qr[2],cr[2]) job = qiskit.execute([ghz], backend=backend, shots=5000, noise_model=noise_model) results = job.result() # Results without mitigation raw_counts = results.get_counts() # Get the filter object meas_filter = meas_fitter.filter # Results with mitigation mitigated_results = meas_filter.apply(results) mitigated_counts = mitigated_results.get_counts(0) from qiskit.tools.visualization import * plot_histogram([raw_counts, mitigated_counts], legend=['raw', 'mitigated']) # Make a 3Q GHZ state cr = ClassicalRegister(3) ghz = QuantumCircuit(qr, cr) ghz.h(qr[0]) ghz.cx(qr[0], qr[1]) ghz.cx(qr[1], qr[2]) # 明示的にbig endianにしてみる ghz.measure(qr[0],cr[2]) ghz.measure(qr[1],cr[1]) ghz.measure(qr[2],cr[0]) job = qiskit.execute([ghz], backend=backend, shots=5000, noise_model=noise_model) results = job.result() # Results without mitigation raw_counts = results.get_counts() # Get the filter object meas_filter = meas_fitter.filter # Results with mitigation mitigated_results = meas_filter.apply(results) mitigated_counts = mitigated_results.get_counts(0) from qiskit.tools.visualization import * plot_histogram([raw_counts, mitigated_counts], legend=['raw', 'mitigated'])
https://github.com/BOBO1997/osp_solutions	BOBO1997	import re import numpy as np import matplotlib.pyplot as plt import itertools import random import pickle plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 100 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits # qr = QuantumRegister(7) qc = QuantumCircuit(3) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([1,0]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) qc.x([1]) # encoding # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [1, 0]) qc.cx(1, 2) qc.cx(0, 1) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) # circuit optimization t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [2, 1, 0]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates # Pauli Twirling def pauli_twirling(circ: str) -> QuantumCircuit: """ そのまま使う: 修正は後回し """ #! qasm ベタ書き def apply_pauli(num: int, qb: int) -> str: if (num == 0): return f'id q[{qb}];\n' elif (num == 1): return f'x q[{qb}];\n' elif (num == 2): return f'y q[{qb}];\n' else: return f'z q[{qb}];\n' paulis = [(i,j) for i in range(0,4) for j in range(0,4)] paulis.remove((0,0)) paulis_map = [(0, 1), (3, 2), (3, 3), (1, 1), (1, 0), (2, 3), (2, 2), (2, 1), (2, 0), (1, 3), (1, 2), (3, 0), (3, 1), (0, 2), (0, 3)] new_circ = '' ops = circ.qasm().splitlines(True) #! 生のqasmコードを持ってきてる: オペレータに分解 for op in ops: if (op[:2] == 'cx'): # can add for cz, etc. num = random.randrange(len(paulis)) #! permute paulis qbs = re.findall('q\[(.)\]', op) new_circ += apply_pauli(paulis[num][0], qbs[0]) new_circ += apply_pauli(paulis[num][1], qbs[1]) new_circ += op new_circ += apply_pauli(paulis_map[num][0], qbs[0]) new_circ += apply_pauli(paulis_map[num][1], qbs[1]) else: new_circ += op return QuantumCircuit.from_qasm_str(new_circ) def zne_wrapper(qcs, scale_factors = [1.0, 2.0, 3.0]): """ """ folded_qcs = [] #! ZNE用の回路 for qc in qcs: folded_qcs.append([mitiq.zne.scaling.fold_gates_at_random(qc, scale) for scale in scale_factors]) #! ここでmitiqを使用 folded_qcs = list(itertools.chain(*folded_qcs)) #! folded_qcsを平坦化 folded_qcs = [pauli_twirling(circ) for circ in folded_qcs] #! 後からPauli Twirlingを施す! return folded_qcs zne_qcs = zne_wrapper(st_qcs) print("number of circuits: ", len(zne_qcs)) zne_qcs[-3].draw("mpl") zne_qcs_jakarta = transpile(zne_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"], initial_layout=[5,3,1]) zne_qcs_jakarta = transpile(zne_qcs_jakarta, optimization_level=3, basis_gates=["sx", "cx", "rz"]) from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) print('Job ID', cal_job.job_id()) with open("jakarta_100step.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 15 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # backend = provider.get_backend("ibmq_jakarta") jobs = [] st_qcs_list = [] shots = 1 << 13 # Number of trotter steps trotter_steps = 120 ### CAN BE >= 4 for num_steps in range(1, trotter_steps + 1, 10): print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(num_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/num_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) st_qcs_list.append(st_qcs) # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) print() # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') results = [] for job in jobs: results.append( job.result() ) mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) len(results), len(mit_results) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition raw_fids = [] for result in results: fid = state_tomo(result, st_qcs) raw_fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) plt.clf() plt.title("fidelity with QREM") plt.plot(range(1, trotter_steps + 1, 10), raw_fids) plt.plot(range(1, trotter_steps + 1, 10), fids) plt.xlabel("number of trotter steps") plt.ylabel("fidelity") for i, fid in enumerate(raw_fids): print(i+1, fid) for i, fid in enumerate(fids): print(i+1, fid) st_qcs_list[-1][-1].draw("mpl") st_qcs_list[-2][-1].draw("mpl")
https://github.com/BOBO1997/osp_solutions	BOBO1997	import re import numpy as np import matplotlib.pyplot as plt import itertools import random import pickle plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 100 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits # qr = QuantumRegister(7) qc = QuantumCircuit(3) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([1,0]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) qc.x([1]) # encoding # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [1, 0]) qc.cx(1, 2) qc.cx(0, 1) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) # circuit optimization t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [2, 1, 0]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates def zne_wrapper(qcs, scale_factors = [1.0, 2.0, 3.0]): """ """ folded_qcs = [] #! ZNE用の回路 for qc in qcs: folded_qcs.append([mitiq.zne.scaling.fold_gates_at_random(qc, scale) for scale in scale_factors]) #! ここでmitiqを使用 folded_qcs = list(itertools.chain(*folded_qcs)) #! folded_qcsを平坦化 return folded_qcs zne_qcs = zne_wrapper(st_qcs) print("number of circuits: ", len(zne_qcs)) zne_qcs[-3].draw("mpl") zne_qcs_jakarta = transpile(zne_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"], initial_layout=[5,3,1]) zne_qcs_jakarta = transpile(zne_qcs_jakarta, optimization_level=3, basis_gates=["sx", "cx", "rz"]) zne_qcs_jakarta[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for job in jobs: mit_results.append( meas_fitter.filter.apply(job.result()) ) # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	# -- coding: utf-8 -- # This code is part of Qiskit. # # (C) Copyright IBM 2018, 2019. # # This code is licensed under the Apache License, Version 2.0. You may # obtain a copy of this license in the LICENSE.txt file in the root directory # of this source tree or at http://www.apache.org/licenses/LICENSE-2.0. # # Any modifications or derivative works of this code must retain this # copyright notice, and modified files need to carry a notice indicating # that they have been altered from the originals. import numpy as np from qiskit import compiler, BasicAer, QuantumRegister from qiskit.converters import circuit_to_dag from qiskit.transpiler import PassManager from qiskit.transpiler.passes import Unroller def convert_to_basis_gates(circuit): # unroll the circuit using the basis u1, u2, u3, cx, and id gates unroller = Unroller(basis=['u1', 'u2', 'u3', 'cx', 'id']) pm = PassManager(passes=[unroller]) qc = compiler.transpile(circuit, BasicAer.get_backend('qasm_simulator'), pass_manager=pm) return qc def is_qubit(qb): # check if the input is a qubit, which is in the form (QuantumRegister, int) return isinstance(qb, tuple) and isinstance(qb[0], QuantumRegister) and isinstance(qb[1], int) def is_qubit_list(qbs): # check if the input is a list of qubits for qb in qbs: if not is_qubit(qb): return False return True def summarize_circuits(circuits): """Summarize circuits based on QuantumCircuit, and four metrics are summarized. Number of qubits and classical bits, and number of operations and depth of circuits. The average statistic is provided if multiple circuits are inputed. Args: circuits (QuantumCircuit or [QuantumCircuit]): the to-be-summarized circuits """ if not isinstance(circuits, list): circuits = [circuits] ret = "" ret += "Submitting {} circuits.\n".format(len(circuits)) ret += "============================================================================\n" stats = np.zeros(4) for i, circuit in enumerate(circuits): dag = circuit_to_dag(circuit) depth = dag.depth() width = dag.width() size = dag.size() classical_bits = dag.num_cbits() op_counts = dag.count_ops() stats[0] += width stats[1] += classical_bits stats[2] += size stats[3] += depth ret = ''.join([ret, "{}-th circuit: {} qubits, {} classical bits and {} operations with depth {}\n op_counts: {}\n".format( i, width, classical_bits, size, depth, op_counts)]) if len(circuits) > 1: stats /= len(circuits) ret = ''.join([ret, "Average: {:.2f} qubits, {:.2f} classical bits and {:.2f} operations with depth {:.2f}\n".format( stats[0], stats[1], stats[2], stats[3])]) ret += "============================================================================\n" return ret
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors=scale_factors, fac_type="lin") target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") # QREM shots = 1 << 13 qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) jobs.append(job) dt_now = datetime.datetime.now() import pickle with open("jobs_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("job_ids_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_jakarta" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) # Compute tomography fidelities for each repetition raw_fids = [] for result in results: fid = state_tomo(result, st_qcs) raw_fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) plt.clf() plt.style.use('ggplot') plt.figure(dpi=200) plt.title("state fidelity from Trotter step 1 to "+str(trotter_steps)) plt.plot(trotter_steps, raw_fids, label="raw fidelity") plt.plot(trotter_steps, fids, label="fidelity after QREM") plt.xlabel("number of trotter steps") plt.ylabel("fidelity") plt.grid(linestyle='dotted') for step, fid in zip(trotter_steps, raw_fids): print(step, fid) for step, fid in zip(trotter_steps, fids): print(step, fid)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import re import itertools import numpy as np import random random.seed(42) import mitiq from qiskit import QuantumCircuit, QuantumRegister from qiskit.ignis.mitigation import expectation_value # Pauli Twirling def pauli_twirling(circ: QuantumCircuit) -> QuantumCircuit: """ [internal function] This function takes a quantum circuit and return a new quantum circuit with Pauli Twirling around the CNOT gates. Args: circ: QuantumCircuit Returns: QuantumCircuit """ def apply_pauli(num: int, qb: int) -> str: if (num == 0): return f'' elif (num == 1): return f'x q[{qb}];\n' elif (num == 2): return f'y q[{qb}];\n' else: return f'z q[{qb}];\n' paulis = [(i,j) for i in range(0,4) for j in range(0,4)] paulis.remove((0,0)) paulis_map = [(0, 1), (3, 2), (3, 3), (1, 1), (1, 0), (2, 3), (2, 2), (2, 1), (2, 0), (1, 3), (1, 2), (3, 0), (3, 1), (0, 2), (0, 3)] new_circ = '' ops = circ.qasm().splitlines(True) #! split the quantum circuit into qasm operators for op in ops: if (op[:2] == 'cx'): # add Pauli Twirling around the CNOT gate num = random.randrange(len(paulis)) qbs = re.findall('q\[(.)\]', op) new_circ += apply_pauli(paulis[num][0], qbs[0]) new_circ += apply_pauli(paulis[num][1], qbs[1]) new_circ += op new_circ += apply_pauli(paulis_map[num][0], qbs[0]) new_circ += apply_pauli(paulis_map[num][1], qbs[1]) else: new_circ += op return QuantumCircuit.from_qasm_str(new_circ) def zne_wrapper(qcs, scale_factors = [1.0, 2.0, 3.0], pt = False): """ This function outputs the circuit list for zero-noise extrapolation. Args: qcs: List[QuantumCircuit], the input quantum circuits. scale_factors: List[float], to what extent the noise scales are investigated. pt: bool, whether add Pauli Twirling or not. Returns: folded_qcs: List[QuantumCircuit] """ folded_qcs = [] #! ZNE用の回路 for qc in qcs: folded_qcs.append([mitiq.zne.scaling.fold_gates_at_random(qc, scale) for scale in scale_factors]) #! ここでmitiqを使用 folded_qcs = list(itertools.chain(folded_qcs)) #! folded_qcsを平坦化 if pt: folded_qcs = [pauli_twirling(circ) for circ in folded_qcs] return folded_qcs def make_stf_basis(n, basis_elements = ["X","Y","Z"]): """ [internal function] This function outputs all the combinations of length n string for given basis_elements. When basis_elements is X, Y, and Z (default), the output becomes the n-qubit Pauli basis. Args: n: int basis_elements: List[str] Returns: basis: List[str] """ if n == 1: return basis_elements basis = [] for i in basis_elements: sub_basis = make_stf_basis(n - 1, basis_elements) basis += [i + j for j in sub_basis] return basis def reduce_hist(hist, poses): """ [internal function] This function returns the reduced histogram to the designated positions. Args: hist: Dict[str, float] poses: List[int] Returns: ret_hist: Dict[str, float] """ n = len(poses) ret_hist = {format(i, "0" + str(n) + "b"): 0 for i in range(1 << n)} for k, v in hist.items(): pos = "" for i in range(n): pos += k[poses[i]] ret_hist[pos] += v return ret_hist def make_stf_expvals(n, stf_hists): """ [internal function] This function create the expectations under expanded basis, which are used to reconstruct the density matrix. Args: n: int, the size of classical register in the measurement results. stf_hists: List[Dict[str, float]], the input State Tomography Fitter histograms. Returns: st_expvals: List[float], the output State Tomography expectation values. """ assert len(stf_hists) == 3 * n stf_basis = make_stf_basis(n, basis_elements=["X","Y","Z"]) st_basis = make_stf_basis(n, basis_elements=["I","X","Y","Z"]) stf_hists_dict = {basis: hist for basis, hist in zip(stf_basis, stf_hists)} st_hists_dict = {basis: stf_hists_dict.get(basis, None) for basis in st_basis} # remaining for basis in sorted(set(st_basis) - set(stf_basis)): if basis == "I" * n: continue reduction_poses = [] reduction_basis = "" for i, b in enumerate(basis): if b != "I": reduction_poses.append(n - 1 - i) # big endian reduction_basis += b # こっちはそのまま(なぜならラベルはlittle endianだから) else: reduction_basis += "Z" st_hists_dict[basis] = reduce_hist(stf_hists_dict[reduction_basis], reduction_poses) st_expvals = dict() for basis, hist in st_hists_dict.items(): if basis == "I" * n: st_expvals[basis] = 1.0 continue st_expvals[basis], _ = expectation_value(hist) return st_expvals def zne_decoder(n, result, scale_factors=[1.0, 2.0, 3.0], fac_type="lin"): """ This function applies the zero-noise extrapolation to the measured results and output the mitigated zero-noise expectation values. Args: n: int, the size of classical register in the measurement results. result: Result, the returned results from job. scale_factors: List[float], this should be the same as the zne_wrapper. fac_type: str, "lin" or "exp", whether to use LinFactory option or ExpFactory option in mitiq, to extrapolate the expectation values. Returns: zne_expvals: List[float], the mitigated zero-noise expectation values. """ hists = result.get_counts() num_scale_factors = len(scale_factors) assert len(hists) % num_scale_factors == 0 scale_wise_expvals = [] # num_scale_factors * 64 for i in range(num_scale_factors): scale_wise_hists = [hists[3 * j + i] for j in range(len(hists) // num_scale_factors)] st_expvals = make_stf_expvals(n, scale_wise_hists) scale_wise_expvals.append( list(st_expvals.values()) ) scale_wise_expvals = np.array(scale_wise_expvals) linfac = mitiq.zne.inference.LinearFactory(scale_factors) expfac = mitiq.zne.ExpFactory(scale_factors) zne_expvals = [] for i in range(4 ** n): if fac_type == "lin": zne_expvals.append( linfac.extrapolate(scale_factors, scale_wise_expvals[:, i]) ) else: zne_expvals.append( expfac.extrapolate(scale_factors, scale_wise_expvals[:, i]) ) return zne_expvals
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors=scale_factors, fac_type="lin") target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") # QREM shots = 1 << 13 qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) jobs.append(job) dt_now = datetime.datetime.now() import pickle with open("jobs_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("job_ids_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_jakarta" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) # Compute tomography fidelities for each repetition raw_fids = [] for result in results: fid = state_tomo(result, st_qcs) raw_fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) # print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) plt.clf() plt.style.use('ggplot') plt.figure(dpi=200) plt.title("state fidelity from Trotter step 1 to "+str(trotter_steps)) plt.plot(trotter_steps, raw_fids, label="raw fidelity") plt.plot(trotter_steps, fids, label="fidelity after QREM") plt.xlabel("number of trotter steps") plt.ylabel("fidelity") plt.grid(linestyle='dotted') for step, fid in zip(trotter_steps, raw_fids): print(step, fid) for step, fid in zip(trotter_steps, fids): print(step, fid)
https://github.com/BOBO1997/osp_solutions	BOBO1997	# -- coding: utf-8 -- # This code is part of Qiskit. # # (C) Copyright IBM 2018, 2019. # # This code is licensed under the Apache License, Version 2.0. You may # obtain a copy of this license in the LICENSE.txt file in the root directory # of this source tree or at http://www.apache.org/licenses/LICENSE-2.0. # # Any modifications or derivative works of this code must retain this # copyright notice, and modified files need to carry a notice indicating # that they have been altered from the originals. import numpy as np from qiskit import compiler, BasicAer, QuantumRegister from qiskit.converters import circuit_to_dag from qiskit.transpiler import PassManager from qiskit.transpiler.passes import Unroller def convert_to_basis_gates(circuit): # unroll the circuit using the basis u1, u2, u3, cx, and id gates unroller = Unroller(basis=['u1', 'u2', 'u3', 'cx', 'id']) pm = PassManager(passes=[unroller]) qc = compiler.transpile(circuit, BasicAer.get_backend('qasm_simulator'), pass_manager=pm) return qc def is_qubit(qb): # check if the input is a qubit, which is in the form (QuantumRegister, int) return isinstance(qb, tuple) and isinstance(qb[0], QuantumRegister) and isinstance(qb[1], int) def is_qubit_list(qbs): # check if the input is a list of qubits for qb in qbs: if not is_qubit(qb): return False return True def summarize_circuits(circuits): """Summarize circuits based on QuantumCircuit, and four metrics are summarized. Number of qubits and classical bits, and number of operations and depth of circuits. The average statistic is provided if multiple circuits are inputed. Args: circuits (QuantumCircuit or [QuantumCircuit]): the to-be-summarized circuits """ if not isinstance(circuits, list): circuits = [circuits] ret = "" ret += "Submitting {} circuits.\n".format(len(circuits)) ret += "============================================================================\n" stats = np.zeros(4) for i, circuit in enumerate(circuits): dag = circuit_to_dag(circuit) depth = dag.depth() width = dag.width() size = dag.size() classical_bits = dag.num_cbits() op_counts = dag.count_ops() stats[0] += width stats[1] += classical_bits stats[2] += size stats[3] += depth ret = ''.join([ret, "{}-th circuit: {} qubits, {} classical bits and {} operations with depth {}\n op_counts: {}\n".format( i, width, classical_bits, size, depth, op_counts)]) if len(circuits) > 1: stats /= len(circuits) ret = ''.join([ret, "Average: {:.2f} qubits, {:.2f} classical bits and {:.2f} operations with depth {:.2f}\n".format( stats[0], stats[1], stats[2], stats[3])]) ret += "============================================================================\n" return ret
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors=scale_factors, fac_type="lin") target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") # QREM shots = 1 << 13 qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) jobs.append(job) dt_now = datetime.datetime.now() import pickle with open("jobs_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("job_ids_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_jakarta" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) with open("job_ids_jakarta_100step_20220411_030032_.pkl", "rb") as f: job_ids_dict = pickle.load(f) job_ids_dict['job_ids'] = job_ids_dict['job_ids'][:3] job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] job_ids, cal_job_id retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) # make the complete QREM fitter qr = QuantumRegister(num_qubits) _, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') retrieved_results = [] for i in range(len(retrieved_jobs)): retrieved_results.append(retrieved_jobs[i].result()) from qiskit.result import Result labels = \ [('X', 'X', 'X'), ('X', 'X', 'Y'), ('X', 'X', 'Z'), ('X', 'Y', 'X'), ('X', 'Y', 'Y'), ('X', 'Y', 'Z'), ('X', 'Z', 'X'), ('X', 'Z', 'Y'), ('X', 'Z', 'Z'), ('Y', 'X', 'X'), ('Y', 'X', 'Y'), ('Y', 'X', 'Z'), ('Y', 'Y', 'X'), ('Y', 'Y', 'Y'), ('Y', 'Y', 'Z'), ('Y', 'Z', 'X'), ('Y', 'Z', 'Y'), ('Y', 'Z', 'Z'), ('Z', 'X', 'X'), ('Z', 'X', 'Y'), ('Z', 'X', 'Z'), ('Z', 'Y', 'X'), ('Z', 'Y', 'Y'), ('Z', 'Y', 'Z'), ('Z', 'Z', 'X'), ('Z', 'Z', 'Y'), ('Z', 'Z', 'Z'), ] retrieved_results[0].results[0].header reshaped_results = [] for result in retrieved_results: res1 = Result(backend_name=result.backend_name, backend_version=result.backend_version, qobj_id=result.qobj_id, job_id=result.job_id, success=result.success, results=[]) res2 = Result(backend_name=result.backend_name, backend_version=result.backend_version, qobj_id=result.qobj_id, job_id=result.job_id, success=result.success, results=[]) res3 = Result(backend_name=result.backend_name, backend_version=result.backend_version, qobj_id=result.qobj_id, job_id=result.job_id, success=result.success, results=[]) for i, label in enumerate(labels): result.results[3 * i].name = str(label) result.results[3 * i].header.name = str(label) result.results[3 * i + 1].name = str(label) result.results[3 * i + 1].header.name = str(label) result.results[3 * i + 2].name = str(label) result.results[3 * i + 2].header.name = str(label) res1.results.append(result.results[3 * i]) res2.results.append(result.results[3 * i + 1]) res3.results.append(result.results[3 * i + 2]) reshaped_results += [res1, res2, res3] from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") st_qcs[0].name # Compute tomography fidelities for each repetition fids = [] for result in reshaped_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) fids reshaped_results[0].results[0] str(('X', 'X', 'X'))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import re import itertools import numpy as np import random random.seed(42) import mitiq from qiskit import QuantumCircuit, QuantumRegister from qiskit.ignis.mitigation import expectation_value # Pauli Twirling def pauli_twirling(circ: QuantumCircuit) -> QuantumCircuit: """ [internal function] This function takes a quantum circuit and return a new quantum circuit with Pauli Twirling around the CNOT gates. Args: circ: QuantumCircuit Returns: QuantumCircuit """ def apply_pauli(num: int, qb: int) -> str: if (num == 0): return f'' elif (num == 1): return f'x q[{qb}];\n' elif (num == 2): return f'y q[{qb}];\n' else: return f'z q[{qb}];\n' paulis = [(i,j) for i in range(0,4) for j in range(0,4)] paulis.remove((0,0)) paulis_map = [(0, 1), (3, 2), (3, 3), (1, 1), (1, 0), (2, 3), (2, 2), (2, 1), (2, 0), (1, 3), (1, 2), (3, 0), (3, 1), (0, 2), (0, 3)] new_circ = '' ops = circ.qasm().splitlines(True) #! split the quantum circuit into qasm operators for op in ops: if (op[:2] == 'cx'): # add Pauli Twirling around the CNOT gate num = random.randrange(len(paulis)) qbs = re.findall('q\[(.)\]', op) new_circ += apply_pauli(paulis[num][0], qbs[0]) new_circ += apply_pauli(paulis[num][1], qbs[1]) new_circ += op new_circ += apply_pauli(paulis_map[num][0], qbs[0]) new_circ += apply_pauli(paulis_map[num][1], qbs[1]) else: new_circ += op return QuantumCircuit.from_qasm_str(new_circ) def zne_wrapper(qcs, scale_factors = [1.0, 2.0, 3.0], pt = False): """ This function outputs the circuit list for zero-noise extrapolation. Args: qcs: List[QuantumCircuit], the input quantum circuits. scale_factors: List[float], to what extent the noise scales are investigated. pt: bool, whether add Pauli Twirling or not. Returns: folded_qcs: List[QuantumCircuit] """ folded_qcs = [] #! ZNE用の回路 for qc in qcs: folded_qcs.append([mitiq.zne.scaling.fold_gates_at_random(qc, scale) for scale in scale_factors]) #! ここでmitiqを使用 folded_qcs = list(itertools.chain(folded_qcs)) #! folded_qcsを平坦化 if pt: folded_qcs = [pauli_twirling(circ) for circ in folded_qcs] return folded_qcs def make_stf_basis(n, basis_elements = ["X","Y","Z"]): """ [internal function] This function outputs all the combinations of length n string for given basis_elements. When basis_elements is X, Y, and Z (default), the output becomes the n-qubit Pauli basis. Args: n: int basis_elements: List[str] Returns: basis: List[str] """ if n == 1: return basis_elements basis = [] for i in basis_elements: sub_basis = make_stf_basis(n - 1, basis_elements) basis += [i + j for j in sub_basis] return basis def reduce_hist(hist, poses): """ [internal function] This function returns the reduced histogram to the designated positions. Args: hist: Dict[str, float] poses: List[int] Returns: ret_hist: Dict[str, float] """ n = len(poses) ret_hist = {format(i, "0" + str(n) + "b"): 0 for i in range(1 << n)} for k, v in hist.items(): pos = "" for i in range(n): pos += k[poses[i]] ret_hist[pos] += v return ret_hist def make_stf_expvals(n, stf_hists): """ [internal function] This function create the expectations under expanded basis, which are used to reconstruct the density matrix. Args: n: int, the size of classical register in the measurement results. stf_hists: List[Dict[str, float]], the input State Tomography Fitter histograms. Returns: st_expvals: List[float], the output State Tomography expectation values. """ assert len(stf_hists) == 3 * n stf_basis = make_stf_basis(n, basis_elements=["X","Y","Z"]) st_basis = make_stf_basis(n, basis_elements=["I","X","Y","Z"]) stf_hists_dict = {basis: hist for basis, hist in zip(stf_basis, stf_hists)} st_hists_dict = {basis: stf_hists_dict.get(basis, None) for basis in st_basis} # remaining for basis in sorted(set(st_basis) - set(stf_basis)): if basis == "I" * n: continue reduction_poses = [] reduction_basis = "" for i, b in enumerate(basis): if b != "I": reduction_poses.append(n - 1 - i) # big endian reduction_basis += b # こっちはそのまま(なぜならラベルはlittle endianだから) else: reduction_basis += "Z" st_hists_dict[basis] = reduce_hist(stf_hists_dict[reduction_basis], reduction_poses) st_expvals = dict() for basis, hist in st_hists_dict.items(): if basis == "I" * n: st_expvals[basis] = 1.0 continue st_expvals[basis], _ = expectation_value(hist) return st_expvals def zne_decoder(n, result, scale_factors=[1.0, 2.0, 3.0], fac_type="lin"): """ This function applies the zero-noise extrapolation to the measured results and output the mitigated zero-noise expectation values. Args: n: int, the size of classical register in the measurement results. result: Result, the returned results from job. scale_factors: List[float], this should be the same as the zne_wrapper. fac_type: str, "lin" or "exp", whether to use LinFactory option or ExpFactory option in mitiq, to extrapolate the expectation values. Returns: zne_expvals: List[float], the mitigated zero-noise expectation values. """ hists = result.get_counts() num_scale_factors = len(scale_factors) assert len(hists) % num_scale_factors == 0 scale_wise_expvals = [] # num_scale_factors * 64 for i in range(num_scale_factors): scale_wise_hists = [hists[3 * j + i] for j in range(len(hists) // num_scale_factors)] st_expvals = make_stf_expvals(n, scale_wise_hists) scale_wise_expvals.append( list(st_expvals.values()) ) scale_wise_expvals = np.array(scale_wise_expvals) linfac = mitiq.zne.inference.LinearFactory(scale_factors) expfac = mitiq.zne.ExpFactory(scale_factors) zne_expvals = [] for i in range(4 ** n): if fac_type == "lin": zne_expvals.append( linfac.extrapolate(scale_factors, scale_wise_expvals[:, i]) ) else: zne_expvals.append( expfac.extrapolate(scale_factors, scale_wise_expvals[:, i]) ) return zne_expvals
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors=scale_factors, fac_type="lin") target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") # QREM shots = 1 << 13 qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) jobs.append(job) dt_now = datetime.datetime.now() import pickle with open("jobs_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("job_ids_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_jakarta" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) with open("job_ids_jakarta_100step_20220411_030032_.pkl", "rb") as f: job_ids_dict = pickle.load(f) job_ids_dict['job_ids'] = job_ids_dict['job_ids'][:3] job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] job_ids, cal_job_id retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) # make the complete QREM fitter qr = QuantumRegister(num_qubits) _, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') retrieved_results = [] for i in range(len(retrieved_jobs)): retrieved_results.append(retrieved_jobs[i].result()) from qiskit.result import Result labels = \ [('X', 'X', 'X'), ('X', 'X', 'Y'), ('X', 'X', 'Z'), ('X', 'Y', 'X'), ('X', 'Y', 'Y'), ('X', 'Y', 'Z'), ('X', 'Z', 'X'), ('X', 'Z', 'Y'), ('X', 'Z', 'Z'), ('Y', 'X', 'X'), ('Y', 'X', 'Y'), ('Y', 'X', 'Z'), ('Y', 'Y', 'X'), ('Y', 'Y', 'Y'), ('Y', 'Y', 'Z'), ('Y', 'Z', 'X'), ('Y', 'Z', 'Y'), ('Y', 'Z', 'Z'), ('Z', 'X', 'X'), ('Z', 'X', 'Y'), ('Z', 'X', 'Z'), ('Z', 'Y', 'X'), ('Z', 'Y', 'Y'), ('Z', 'Y', 'Z'), ('Z', 'Z', 'X'), ('Z', 'Z', 'Y'), ('Z', 'Z', 'Z'), ] retrieved_results[0].results[0].header reshaped_results = [] for result in retrieved_results: res1 = Result(backend_name=result.backend_name, backend_version=result.backend_version, qobj_id=result.qobj_id, job_id=result.job_id, success=result.success, results=[]) res2 = Result(backend_name=result.backend_name, backend_version=result.backend_version, qobj_id=result.qobj_id, job_id=result.job_id, success=result.success, results=[]) res3 = Result(backend_name=result.backend_name, backend_version=result.backend_version, qobj_id=result.qobj_id, job_id=result.job_id, success=result.success, results=[]) for i, label in enumerate(labels): result.results[3 * i].name = str(label) result.results[3 * i].header.name = str(label) result.results[3 * i + 1].name = str(label) result.results[3 * i + 1].header.name = str(label) result.results[3 * i + 2].name = str(label) result.results[3 * i + 2].header.name = str(label) res1.results.append(result.results[3 * i]) res2.results.append(result.results[3 * i + 1]) res3.results.append(result.results[3 * i + 2]) reshaped_results += [res1, res2, res3] from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder(qc, targets=[0,1,2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") st_qcs[0].name # Compute tomography fidelities for each repetition fids = [] for result in reshaped_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) fids reshaped_results[0].results[0] str(('X', 'X', 'X'))
https://github.com/BOBO1997/osp_solutions	BOBO1997	# -- coding: utf-8 -- # This code is part of Qiskit. # # (C) Copyright IBM 2018, 2019. # # This code is licensed under the Apache License, Version 2.0. You may # obtain a copy of this license in the LICENSE.txt file in the root directory # of this source tree or at http://www.apache.org/licenses/LICENSE-2.0. # # Any modifications or derivative works of this code must retain this # copyright notice, and modified files need to carry a notice indicating # that they have been altered from the originals. import numpy as np from qiskit import compiler, BasicAer, QuantumRegister from qiskit.converters import circuit_to_dag from qiskit.transpiler import PassManager from qiskit.transpiler.passes import Unroller def convert_to_basis_gates(circuit): # unroll the circuit using the basis u1, u2, u3, cx, and id gates unroller = Unroller(basis=['u1', 'u2', 'u3', 'cx', 'id']) pm = PassManager(passes=[unroller]) qc = compiler.transpile(circuit, BasicAer.get_backend('qasm_simulator'), pass_manager=pm) return qc def is_qubit(qb): # check if the input is a qubit, which is in the form (QuantumRegister, int) return isinstance(qb, tuple) and isinstance(qb[0], QuantumRegister) and isinstance(qb[1], int) def is_qubit_list(qbs): # check if the input is a list of qubits for qb in qbs: if not is_qubit(qb): return False return True def summarize_circuits(circuits): """Summarize circuits based on QuantumCircuit, and four metrics are summarized. Number of qubits and classical bits, and number of operations and depth of circuits. The average statistic is provided if multiple circuits are inputed. Args: circuits (QuantumCircuit or [QuantumCircuit]): the to-be-summarized circuits """ if not isinstance(circuits, list): circuits = [circuits] ret = "" ret += "Submitting {} circuits.\n".format(len(circuits)) ret += "============================================================================\n" stats = np.zeros(4) for i, circuit in enumerate(circuits): dag = circuit_to_dag(circuit) depth = dag.depth() width = dag.width() size = dag.size() classical_bits = dag.num_cbits() op_counts = dag.count_ops() stats[0] += width stats[1] += classical_bits stats[2] += size stats[3] += depth ret = ''.join([ret, "{}-th circuit: {} qubits, {} classical bits and {} operations with depth {}\n op_counts: {}\n".format( i, width, classical_bits, size, depth, op_counts)]) if len(circuits) > 1: stats /= len(circuits) ret = ''.join([ret, "Average: {:.2f} qubits, {:.2f} classical bits and {:.2f} operations with depth {:.2f}\n".format( stats[0], stats[1], stats[2], stats[3])]) ret += "============================================================================\n" return ret
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) jobs.append(job) # QREM shots = 1 << 13 qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") # QREM shots = 1 << 13 qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) jobs.append(job) dt_now = datetime.datetime.now() print(dt_now) import pickle with open("jobs_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("job_ids_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_jakarta" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import re import itertools import numpy as np import random random.seed(42) import mitiq from qiskit import QuantumCircuit, QuantumRegister from qiskit.ignis.mitigation import expectation_value # Pauli Twirling def pauli_twirling(circ: QuantumCircuit) -> QuantumCircuit: """ [internal function] This function takes a quantum circuit and return a new quantum circuit with Pauli Twirling around the CNOT gates. Args: circ: QuantumCircuit Returns: QuantumCircuit """ def apply_pauli(num: int, qb: int) -> str: if (num == 0): return f'' elif (num == 1): return f'x q[{qb}];\n' elif (num == 2): return f'y q[{qb}];\n' else: return f'z q[{qb}];\n' paulis = [(i,j) for i in range(0,4) for j in range(0,4)] paulis.remove((0,0)) paulis_map = [(0, 1), (3, 2), (3, 3), (1, 1), (1, 0), (2, 3), (2, 2), (2, 1), (2, 0), (1, 3), (1, 2), (3, 0), (3, 1), (0, 2), (0, 3)] new_circ = '' ops = circ.qasm().splitlines(True) #! split the quantum circuit into qasm operators for op in ops: if (op[:2] == 'cx'): # add Pauli Twirling around the CNOT gate num = random.randrange(len(paulis)) qbs = re.findall('q\[(.)\]', op) new_circ += apply_pauli(paulis[num][0], qbs[0]) new_circ += apply_pauli(paulis[num][1], qbs[1]) new_circ += op new_circ += apply_pauli(paulis_map[num][0], qbs[0]) new_circ += apply_pauli(paulis_map[num][1], qbs[1]) else: new_circ += op return QuantumCircuit.from_qasm_str(new_circ) def zne_wrapper(qcs, scale_factors = [1.0, 2.0, 3.0], pt = False): """ This function outputs the circuit list for zero-noise extrapolation. Args: qcs: List[QuantumCircuit], the input quantum circuits. scale_factors: List[float], to what extent the noise scales are investigated. pt: bool, whether add Pauli Twirling or not. Returns: folded_qcs: List[QuantumCircuit] """ folded_qcs = [] #! ZNE用の回路 for qc in qcs: folded_qcs.append([mitiq.zne.scaling.fold_gates_at_random(qc, scale) for scale in scale_factors]) #! ここでmitiqを使用 folded_qcs = list(itertools.chain(folded_qcs)) #! folded_qcsを平坦化 if pt: folded_qcs = [pauli_twirling(circ) for circ in folded_qcs] return folded_qcs def make_stf_basis(n, basis_elements = ["X","Y","Z"]): """ [internal function] This function outputs all the combinations of length n string for given basis_elements. When basis_elements is X, Y, and Z (default), the output becomes the n-qubit Pauli basis. Args: n: int basis_elements: List[str] Returns: basis: List[str] """ if n == 1: return basis_elements basis = [] for i in basis_elements: sub_basis = make_stf_basis(n - 1, basis_elements) basis += [i + j for j in sub_basis] return basis def reduce_hist(hist, poses): """ [internal function] This function returns the reduced histogram to the designated positions. Args: hist: Dict[str, float] poses: List[int] Returns: ret_hist: Dict[str, float] """ n = len(poses) ret_hist = {format(i, "0" + str(n) + "b"): 0 for i in range(1 << n)} for k, v in hist.items(): pos = "" for i in range(n): pos += k[poses[i]] ret_hist[pos] += v return ret_hist def make_stf_expvals(n, stf_hists): """ [internal function] This function create the expectations under expanded basis, which are used to reconstruct the density matrix. Args: n: int, the size of classical register in the measurement results. stf_hists: List[Dict[str, float]], the input State Tomography Fitter histograms. Returns: st_expvals: List[float], the output State Tomography expectation values. """ assert len(stf_hists) == 3 * n stf_basis = make_stf_basis(n, basis_elements=["X","Y","Z"]) st_basis = make_stf_basis(n, basis_elements=["I","X","Y","Z"]) stf_hists_dict = {basis: hist for basis, hist in zip(stf_basis, stf_hists)} st_hists_dict = {basis: stf_hists_dict.get(basis, None) for basis in st_basis} # remaining for basis in sorted(set(st_basis) - set(stf_basis)): if basis == "I" * n: continue reduction_poses = [] reduction_basis = "" for i, b in enumerate(basis): if b != "I": reduction_poses.append(n - 1 - i) # big endian reduction_basis += b # こっちはそのまま(なぜならラベルはlittle endianだから) else: reduction_basis += "Z" st_hists_dict[basis] = reduce_hist(stf_hists_dict[reduction_basis], reduction_poses) st_expvals = dict() for basis, hist in st_hists_dict.items(): if basis == "I" * n: st_expvals[basis] = 1.0 continue st_expvals[basis], _ = expectation_value(hist) return st_expvals def zne_decoder(n, result, scale_factors=[1.0, 2.0, 3.0], fac_type="lin"): """ This function applies the zero-noise extrapolation to the measured results and output the mitigated zero-noise expectation values. Args: n: int, the size of classical register in the measurement results. result: Result, the returned results from job. scale_factors: List[float], this should be the same as the zne_wrapper. fac_type: str, "lin" or "exp", whether to use LinFactory option or ExpFactory option in mitiq, to extrapolate the expectation values. Returns: zne_expvals: List[float], the mitigated zero-noise expectation values. """ hists = result.get_counts() num_scale_factors = len(scale_factors) assert len(hists) % num_scale_factors == 0 scale_wise_expvals = [] # num_scale_factors * 64 for i in range(num_scale_factors): scale_wise_hists = [hists[3 * j + i] for j in range(len(hists) // num_scale_factors)] st_expvals = make_stf_expvals(n, scale_wise_hists) scale_wise_expvals.append( list(st_expvals.values()) ) scale_wise_expvals = np.array(scale_wise_expvals) linfac = mitiq.zne.inference.LinearFactory(scale_factors) expfac = mitiq.zne.ExpFactory(scale_factors) zne_expvals = [] for i in range(4 ** n): if fac_type == "lin": zne_expvals.append( linfac.extrapolate(scale_factors, scale_wise_expvals[:, i]) ) else: zne_expvals.append( expfac.extrapolate(scale_factors, scale_wise_expvals[:, i]) ) return zne_expvals
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) jobs.append(job) # QREM shots = 1 << 13 qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") # QREM shots = 1 << 13 qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) jobs.append(job) dt_now = datetime.datetime.now() import pickle with open("jobs_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("job_ids_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_jakarta" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") t3_st_qcs = transpile(t3_st_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_st_qcs), ")") t3_st_qcs[-1].draw("mpl") # only view trotter gates # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(t3_st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout=initial_layout) print('Job ID', cal_job.job_id()) dt_now = datetime.datetime.now() print(dt_now) with open("jobs_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("job_ids_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_jakarta" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) cal_results = cal_job.result() print("retrieved cal_results") meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for i, job in enumerate(jobs): mit_results.append( meas_fitter.filter.apply(job.result()) ) print("retrieved", i, "th results") # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") t3_st_qcs = transpile(t3_st_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_st_qcs), ")") t3_st_qcs[-1].draw("mpl") # only view trotter gates from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(t3_st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout=initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() print("retrieved cal_results") meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for i, job in enumerate(jobs): mit_results.append( meas_fitter.filter.apply(job.result()) ) print("retrieved", i, "th results") # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 15 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout=[5,3,1]) print('Job ID', cal_job.job_id()) dt_now = datetime.datetime.now() print(dt_now) with open("jobs_jakarta_50step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("job_ids_jakarta_50step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_jakarta" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) with open("jakarta_50step.pkl", "rb") as f: job_list = pickle.load(f) jobs = job_list["jobs"] cal_job = job_list["cal_job"] cal_results = cal_job.result() print("retrieved cal_results") meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for i, job in enumerate(jobs): mit_results.append( meas_fitter.filter.apply(job.result()) ) print("retrieved", i, "th results") # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = 50 ### CAN BE >= 4 # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(trotter_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/trotter_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs[-1].draw("mpl") # only view trotter gates # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout=[5,3,1]) print('Job ID', cal_job.job_id()) dt_now = datetime.datetime.now() print(dt_now) with open("jobs_jakarta_50step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("job_ids_jakarta_50step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_jakarta" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) with open("jakarta_50step.pkl", "rb") as f: job_list = pickle.load(f) jobs = job_list["jobs"] cal_job = job_list["cal_job"] cal_results = cal_job.result() print("retrieved cal_results") meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for i, job in enumerate(jobs): mit_results.append( meas_fitter.filter.apply(job.result()) ) print("retrieved", i, "th results") # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.providers.aer import QasmSimulator from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity # Suppress warnings import warnings warnings.filterwarnings('ignore') def trotter_gate(dt, to_instruction = True): qc = QuantumCircuit(2) qc.rx(2dt,0) qc.rz(2dt,1) qc.h(1) qc.cx(1,0) qc.rz(-2dt, 0) qc.rx(-2dt, 1) qc.rz(2dt, 1) qc.cx(1,0) qc.h(1) qc.rz(2dt, 0) return qc.to_instruction() if to_instruction else qc trotter_gate(np.pi / 6, to_instruction=False).draw("mpl") # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate Trot_gate = trotter_gate(dt) # Number of trotter steps trotter_steps = list(range(1,10)) + list(range(10, 101, 10)) st_qcs_list = [] for num_steps in trotter_steps: # Initialize quantum circuit for 3 qubits qr = QuantumRegister(7) qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) qc.x([5]) # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Simulate time evolution under H_heis3 Hamiltonian for _ in range(num_steps): qc.append(Trot_gate, [qr[3], qr[5]]) qc.cx(qr[3], qr[1]) qc.cx(qr[5], qr[3]) # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time/num_steps}) t3_qc = transpile(qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_qc = transpile(t3_qc, optimization_level=3, basis_gates=["sx", "cx", "rz"]) # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(t3_qc, [qr[1], qr[3], qr[5]]) st_qcs_list.append(st_qcs) # Display circuit for confirmation # st_qcs[-1].decompose().draw() # view decomposition of trotter gates st_qcs_list[-1][-1].draw("mpl") # only view trotter gates from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout=[5,3,1]) print('Job ID', cal_job.job_id()) dt_now = datetime.datetime.now() print(dt_now) with open("jobs_jakarta_50step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("job_ids_jakarta_50step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_jakarta" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) with open("jakarta_50step.pkl", "rb") as f: job_list = pickle.load(f) jobs = job_list["jobs"] cal_job = job_list["cal_job"] cal_results = cal_job.result() print("retrieved cal_results") meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = [] for i, job in enumerate(jobs): mit_results.append( meas_fitter.filter.apply(job.result()) ) print("retrieved", i, "th results") # Compute the state tomography based on the st_qcs quantum circuits and the results from those ciricuits def state_tomo(result, st_qcs): # The expected final state; necessary to determine state tomography fidelity target_state = (One^One^Zero).to_matrix() # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) # Fit state tomography results tomo_fitter = StateTomographyFitter(result, st_qcs) rho_fit = tomo_fitter.fit(method='lstsq') # Compute fidelity fid = state_fidelity(rho_fit, target_state) return fid # Compute tomography fidelities for each repetition fids = [] for result in mit_results: fid = state_tomo(result, st_qcs) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors=scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 1 # unused # Number of trotter steps print("trotter step: ", num_steps) # execute: reps = 1 job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! rho = expvals_to_valid_rho(num_qubits, zne_expvals) fidelity = state_fidelity(rho, target_state) print(fidelity)
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) jobs.append(job) # QREM shots = 1 << 13 qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs) print("created zne_qcs (length:", len(zne_qcs), ")") t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-utokyo', group='internal', project='hirashi-jst') provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") # QREM shots = 1 << 13 qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): job = execute(t3_zne_qcs, backend, shots=shots) # 毎回チェック: ここちゃんと変えた？ print('Job ID', job.job_id()) jobs.append(job) dt_now = datetime.datetime.now() import pickle with open("jobs_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("job_ids_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_jakarta" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) cal_results = cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) # with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) # with open(filename, "wb") as f: # pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) # with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump(backend.properties(), f) retrieved_jobs = jobs retrieved_cal_job = cal_job cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = t3_st_qcs # zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = False) # print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) # with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) # with open(filename, "wb") as f: # pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) # with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump(backend.properties(), f) retrieved_jobs = jobs retrieved_cal_job = cal_job cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: # mit_results = meas_fitter.filter.apply(job.result()) rho = StateTomographyFitter(job.result(), t3_zne_qcs).fit(method='lstsq') fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open(filename, "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) filename = "job_ids_ibmq_jakarta_100step_20220413_030821_.pkl" # change here with open(filename, "rb") as f: job_ids_dict = pickle.load(f) job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) import qiskit.tools.jupyter %qiskit_version_table
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") t3_st_qcs = transpile(t3_st_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_st_qcs), ")") t3_st_qcs[-1].draw("mpl") # only view trotter gates # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(t3_st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout=initial_layout) print('Job ID', cal_job.job_id()) dt_now = datetime.datetime.now() print(dt_now) with open("jobs_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("job_ids_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_jakarta" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) filename = "job_ids_jakarta_100step_20220412_171248_.pkl" # change here with open(filename, "rb") as f: job_ids_dict = pickle.load(f) job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') # set the target state target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: # mit_results = meas_fitter.filter.apply(job.result()) # apply QREM rho = StateTomographyFitter(job.result(), st_qcs).fit(method='lstsq') fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) import qiskit.tools.jupyter %qiskit_version_table
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) # with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) # with open(filename, "wb") as f: # pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) # with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump(backend.properties(), f) retrieved_jobs = jobs retrieved_cal_job = cal_job cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = t3_st_qcs # zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = False) # print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) # with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) # with open(filename, "wb") as f: # pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) # with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump(backend.properties(), f) retrieved_jobs = jobs retrieved_cal_job = cal_job cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: # mit_results = meas_fitter.filter.apply(job.result()) rho = StateTomographyFitter(job.result(), t3_zne_qcs).fit(method='lstsq') fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open(filename, "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) filename = "job_ids_ibmq_jakarta_100step_20220413_030821_.pkl" # change here with open(filename, "rb") as f: job_ids_dict = pickle.load(f) job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) import qiskit.tools.jupyter %qiskit_version_table
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") t3_st_qcs = transpile(t3_st_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_st_qcs), ")") t3_st_qcs[-1].draw("mpl") # only view trotter gates # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(t3_st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout=initial_layout) print('Job ID', cal_job.job_id()) dt_now = datetime.datetime.now() print(dt_now) with open("jobs_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("job_ids_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_jakarta" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) filename = "job_ids_jakarta_100step_20220412_171248_.pkl" # change here with open(filename, "rb") as f: job_ids_dict = pickle.load(f) job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') # set the target state target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: # mit_results = meas_fitter.filter.apply(job.result()) # apply QREM rho = StateTomographyFitter(job.result(), st_qcs).fit(method='lstsq') fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) import qiskit.tools.jupyter %qiskit_version_table
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) # with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) # with open(filename, "wb") as f: # pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) # with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump(backend.properties(), f) retrieved_jobs = jobs retrieved_cal_job = cal_job cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open(filename, "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) filename = "job_ids_ibmq_jakarta_100step_20220413_030821_.pkl" # change here with open(filename, "rb") as f: job_ids_dict = pickle.load(f) job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) import qiskit.tools.jupyter %qiskit_version_table
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) # with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) # with open(filename, "wb") as f: # pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) # with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump(backend.properties(), f) retrieved_jobs = jobs retrieved_cal_job = cal_job cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open(filename, "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) filename = "job_ids_ibmq_jakarta_100step_20220413_030821_.pkl" # change here with open(filename, "rb") as f: job_ids_dict = pickle.load(f) job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) import qiskit.tools.jupyter %qiskit_version_table
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) # with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) # with open(filename, "wb") as f: # pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) # with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump(backend.properties(), f) retrieved_jobs = jobs retrieved_cal_job = cal_job cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open(filename, "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) filename = "job_ids_ibmq_jakarta_100step_20220413_030821_.pkl" # change here with open(filename, "rb") as f: job_ids_dict = pickle.load(f) job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) import qiskit.tools.jupyter %qiskit_version_table
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) # with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) # with open(filename, "wb") as f: # pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) # with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump(backend.properties(), f) retrieved_jobs = jobs retrieved_cal_job = cal_job cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open(filename, "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) filename = "job_ids_ibmq_jakarta_100step_20220413_030821_.pkl" # change here with open(filename, "rb") as f: job_ids_dict = pickle.load(f) job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) import qiskit.tools.jupyter %qiskit_version_table
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) # with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) # with open(filename, "wb") as f: # pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) # with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump(backend.properties(), f) retrieved_jobs = jobs retrieved_cal_job = cal_job cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open(filename, "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) filename = "job_ids_ibmq_jakarta_100step_20220413_030821_.pkl" # change here with open(filename, "rb") as f: job_ids_dict = pickle.load(f) job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) import qiskit.tools.jupyter %qiskit_version_table
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) # with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) # with open(filename, "wb") as f: # pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) # with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump(backend.properties(), f) retrieved_jobs = jobs retrieved_cal_job = cal_job cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open(filename, "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) filename = "job_ids_ibmq_jakarta_100step_20220413_030821_.pkl" # change here with open(filename, "rb") as f: job_ids_dict = pickle.load(f) job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) import qiskit.tools.jupyter %qiskit_version_table
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) # with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) # with open(filename, "wb") as f: # pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) # with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump(backend.properties(), f) retrieved_jobs = jobs retrieved_cal_job = cal_job cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = t3_st_qcs # zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = False) # print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) # with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) # with open(filename, "wb") as f: # pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) # with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump(backend.properties(), f) retrieved_jobs = jobs retrieved_cal_job = cal_job cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: # mit_results = meas_fitter.filter.apply(job.result()) rho = StateTomographyFitter(job.result(), t3_zne_qcs).fit(method='lstsq') fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open(filename, "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) filename = "job_ids_ibmq_jakarta_100step_20220413_030821_.pkl" # change here with open(filename, "rb") as f: job_ids_dict = pickle.load(f) job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) import qiskit.tools.jupyter %qiskit_version_table
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle # plt.rcParams.update({'font.size': 16}) # enlarge matplotlib fonts import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("./") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="lq") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") t3_st_qcs = transpile(t3_st_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_st_qcs), ")") t3_st_qcs[-1].draw("mpl") # only view trotter gates # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") shots = 8192 reps = 8 jobs = [] for _ in range(reps): # execute job = execute(t3_st_qcs, backend, shots=shots) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits) meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout=initial_layout) print('Job ID', cal_job.job_id()) dt_now = datetime.datetime.now() print(dt_now) with open("jobs_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open("job_ids_jakarta_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_jakarta" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) filename = "job_ids_jakarta_100step_20220412_171248_.pkl" # change here with open(filename, "rb") as f: job_ids_dict = pickle.load(f) job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') # set the target state target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: # mit_results = meas_fitter.filter.apply(job.result()) # apply QREM rho = StateTomographyFitter(job.result(), st_qcs).fit(method='lstsq') fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) import qiskit.tools.jupyter %qiskit_version_table
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) # with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) # with open(filename, "wb") as f: # pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) # with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump(backend.properties(), f) retrieved_jobs = jobs retrieved_cal_job = cal_job cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits, StateTomographyFitter from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = t3_st_qcs # zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = False) # print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") from qiskit.test.mock import FakeJakarta backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") # IBMQ.load_account() # provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') # print("provider:", provider) # backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) # with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) # with open(filename, "wb") as f: # pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) # with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: # pickle.dump(backend.properties(), f) retrieved_jobs = jobs retrieved_cal_job = cal_job cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: # mit_results = meas_fitter.filter.apply(job.result()) rho = StateTomographyFitter(job.result(), t3_zne_qcs).fit(method='lstsq') fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids)))
https://github.com/BOBO1997/osp_solutions	BOBO1997	import numpy as np import matplotlib.pyplot as plt import itertools from pprint import pprint import pickle import time import datetime # Import qubit states Zero (\|0>) and One (\|1>), and Pauli operators (X, Y, Z) from qiskit.opflow import Zero, One, I, X, Y, Z from qiskit import QuantumCircuit, QuantumRegister, IBMQ, execute, transpile, Aer from qiskit.tools.monitor import job_monitor from qiskit.circuit import Parameter from qiskit.transpiler.passes import RemoveBarriers # Import QREM package from qiskit.ignis.mitigation.measurement import complete_meas_cal, CompleteMeasFitter from qiskit.ignis.mitigation import expectation_value # Import mitiq for zne import mitiq # Import state tomography modules from qiskit.ignis.verification.tomography import state_tomography_circuits from qiskit.quantum_info import state_fidelity import sys import importlib sys.path.append("../utils/") import circuit_utils, zne_utils, tomography_utils, sgs_algorithm importlib.reload(circuit_utils) importlib.reload(zne_utils) importlib.reload(tomography_utils) importlib.reload(sgs_algorithm) from circuit_utils import * from zne_utils import * from tomography_utils import * from sgs_algorithm import * # Combine subcircuits into a single multiqubit gate representing a single trotter step num_qubits = 3 # The final time of the state evolution target_time = np.pi # Parameterize variable t to be evaluated at t=pi later dt = Parameter('t') # Convert custom quantum circuit into a gate trot_gate = trotter_gate(dt) # initial layout initial_layout = [5,3,1] # Number of trotter steps num_steps = 100 print("trotter step: ", num_steps) scale_factors = [1.0, 2.0, 3.0] # Initialize quantum circuit for 3 qubits qr = QuantumRegister(num_qubits, name="q") qc = QuantumCircuit(qr) # Prepare initial state (remember we are only evolving 3 of the 7 qubits on jakarta qubits (q_5, q_3, q_1) corresponding to the state \|110>) make_initial_state(qc, "110") # DO NOT MODIFY (\|q_5,q_3,q_1> = \|110>) subspace_encoder_init110(qc, targets=[0, 1, 2]) # encode trotterize(qc, trot_gate, num_steps, targets=[1, 2]) # Simulate time evolution under H_heis3 Hamiltonian subspace_decoder_init110(qc, targets=[0, 1, 2]) # decode # Evaluate simulation at target_time (t=pi) meaning each trotter step evolves pi/trotter_steps in time qc = qc.bind_parameters({dt: target_time / num_steps}) print("created qc") # Generate state tomography circuits to evaluate fidelity of simulation st_qcs = state_tomography_circuits(qc, [0, 1, 2][::-1]) #! state tomography requires === BIG ENDIAN === print("created st_qcs (length:", len(st_qcs), ")") # remove barriers st_qcs = [RemoveBarriers()(qc) for qc in st_qcs] print("removed barriers from st_qcs") # optimize circuit t3_st_qcs = transpile(st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) t3_st_qcs = transpile(t3_st_qcs, optimization_level=3, basis_gates=["sx", "cx", "rz"]) print("created t3_st_qcs (length:", len(t3_st_qcs), ")") # zne wrapping zne_qcs = zne_wrapper(t3_st_qcs, scale_factors = scale_factors, pt = True) # Pauli Twirling print("created zne_qcs (length:", len(zne_qcs), ")") # optimization_level must be 0 # feed initial_layout here to see the picture of the circuits before casting the job t3_zne_qcs = transpile(zne_qcs, optimization_level=0, basis_gates=["sx", "cx", "rz"], initial_layout=initial_layout) print("created t3_zne_qcs (length:", len(t3_zne_qcs), ")") t3_zne_qcs[-3].draw("mpl") # from qiskit.test.mock import FakeJakarta # backend = FakeJakarta() # backend = Aer.get_backend("qasm_simulator") IBMQ.load_account() provider = IBMQ.get_provider(hub='ibm-q-community', group='ibmquantumawards', project='open-science-22') print("provider:", provider) backend = provider.get_backend("ibmq_jakarta") print(str(backend)) shots = 1 << 13 reps = 8 # unused jobs = [] for _ in range(reps): #! CHECK: run t3_zne_qcs, with optimization_level = 0 and straightforward initial_layout job = execute(t3_zne_qcs, backend, shots=shots, optimization_level=0) print('Job ID', job.job_id()) jobs.append(job) # QREM qr = QuantumRegister(num_qubits, name="calq") meas_calibs, state_labels = complete_meas_cal(qr=qr, circlabel='mcal') # we have to feed initial_layout to calibration matrix cal_job = execute(meas_calibs, backend=backend, shots=shots, optimization_level=3, initial_layout = initial_layout) print('Job ID', cal_job.job_id()) meas_calibs[0].draw("mpl") dt_now = datetime.datetime.now() print(dt_now) filename = "job_ids_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl" print(filename) with open("jobs_" + str(backend) + "_100step_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump({"jobs": jobs, "cal_job": cal_job}, f) with open(filename, "wb") as f: pickle.dump({"job_ids": [job.job_id() for job in jobs], "cal_job_id": cal_job.job_id()}, f) with open("properties_" + str(backend) + "_" + dt_now.strftime('%Y%m%d_%H%M%S') + "_.pkl", "wb") as f: pickle.dump(backend.properties(), f) filename = "job_ids_ibmq_jakarta_100step_20220413_030821_.pkl" # change here with open(filename, "rb") as f: job_ids_dict = pickle.load(f) job_ids = job_ids_dict["job_ids"] cal_job_id = job_ids_dict["cal_job_id"] retrieved_jobs = [] for job_id in job_ids: retrieved_jobs.append(backend.retrieve_job(job_id)) retrieved_cal_job = backend.retrieve_job(cal_job_id) cal_results = retrieved_cal_job.result() meas_fitter = CompleteMeasFitter(cal_results, state_labels, circlabel='mcal') target_state = (One^One^Zero).to_matrix() # DO NOT CHANGE!!! fids = [] for job in retrieved_jobs: mit_results = meas_fitter.filter.apply(job.result()) zne_expvals = zne_decoder(num_qubits, mit_results, scale_factors = scale_factors) rho = expvals_to_valid_rho(num_qubits, zne_expvals) fid = state_fidelity(rho, target_state) fids.append(fid) print('state tomography fidelity = {:.4f} \u00B1 {:.4f}'.format(np.mean(fids), np.std(fids))) import qiskit.tools.jupyter %qiskit_version_table

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