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import os
import sys
import h5py
import numpy as np
import scipy.io
import scipy.signal as signal
from joblib import Parallel, delayed
from scipy.signal import iirnotch
from tqdm import tqdm
_MATRIX_DOF2DOA_TRANSPOSED = np.array(
# https://www.frontiersin.org/articles/10.3389/fnins.2019.00891/full
# Open supplemental data > Data Sheet 1.PDF >
# > SUPPLEMENTARY METHODS > Eqn. S2
# https://www.frontiersin.org/articles/file/downloadfile/461612_supplementary-materials_datasheets_1_pdf/octet-stream/Data%20Sheet%201.PDF/1/461612
[
[+0.6390, +0.0000, +0.0000, +0.0000, +0.0000],
[+0.3830, +0.0000, +0.0000, +0.0000, +0.0000],
[+0.0000, +1.0000, +0.0000, +0.0000, +0.0000],
[-0.6390, +0.0000, +0.0000, +0.0000, +0.0000],
[+0.0000, +0.0000, +0.4000, +0.0000, +0.0000],
[+0.0000, +0.0000, +0.6000, +0.0000, +0.0000],
[+0.0000, +0.0000, +0.0000, +0.4000, +0.0000],
[+0.0000, +0.0000, +0.0000, +0.6000, +0.0000],
[+0.0000, +0.0000, +0.0000, +0.0000, +0.0000],
[+0.0000, +0.0000, +0.0000, +0.0000, +0.1667],
[+0.0000, +0.0000, +0.0000, +0.0000, +0.3333],
[+0.0000, +0.0000, +0.0000, +0.0000, +0.0000],
[+0.0000, +0.0000, +0.0000, +0.0000, +0.1667],
[+0.0000, +0.0000, +0.0000, +0.0000, +0.3333],
[+0.0000, +0.0000, +0.0000, +0.0000, +0.0000],
[+0.0000, +0.0000, +0.0000, +0.0000, +0.0000],
[-0.1900, +0.0000, +0.0000, +0.0000, +0.0000],
[+0.0000, +0.0000, +0.0000, +0.0000, +0.0000],
],
dtype=np.float32,
)
MATRIX_DOF2DOA = _MATRIX_DOF2DOA_TRANSPOSED.T
# βββββββββββββββ Filtering ββββββββββββββββββ
def notch_filter(data, notch_freq=50.0, Q=30.0, fs=1111.0):
"""Notch-filter every channel independently."""
b, a = iirnotch(notch_freq, Q, fs)
out = np.zeros_like(data)
for ch in range(data.shape[1]):
out[:, ch] = signal.filtfilt(b, a, data[:, ch])
return out
def bandpass_filter_emg(emg, lowcut=20.0, highcut=90.0, fs=2000.0, order=4):
nyq = 0.5 * fs
b, a = signal.butter(order, [lowcut / nyq, highcut / nyq], btype="bandpass")
out = np.zeros_like(emg)
for ch in range(emg.shape[1]):
out[:, ch] = signal.filtfilt(b, a, emg[:, ch])
return out
# βββββββββββββββ Sliding window ββββββββββββββ
def sliding_window_segment(emg, label, window_size, stride):
"""
Segment EMG with a sliding window.
Use the frame at the window centre as the segment label / repetition index.
"""
segments, labels = [], []
n_samples = len(label)
for start in range(0, n_samples - window_size + 1, stride):
end = start + window_size
emg_segment = emg[start:end] # (win, ch)
label_segment = label[start:end] # (win, ch)
segments.append(emg_segment)
labels.append(label_segment)
return np.array(segments), np.array(labels)
# βββββββββββββββ Main pipeline βββββββββββββββ
def process_mat_file(mat_path, window_size, stride, fs):
"""
Load one .mat file, filter out NaNs, filter & normalize EMG, map DoFβDoA,
segment, and return (split, segs, labels).
"""
mat = scipy.io.loadmat(mat_path)
emg = mat["emg"] # (T, 16)
label = mat["glove"] # (T, DoF)
# 1) Drop timesteps with any NaNs in glove data
valid = ~np.isnan(label).any(axis=1)
emg = emg[valid]
label = label[valid]
# 3) Z-score per channel
mu = emg.mean(axis=0)
sd = emg.std(axis=0, ddof=1)
sd[sd == 0] = 1.0
emg = (emg - mu) / sd
# 4) DoF β DoA
y_doa = (MATRIX_DOF2DOA @ label.T).T
# 5) Windowing
segs, labs = sliding_window_segment(emg, y_doa, window_size, stride)
# 6) Determine split
fname = os.path.basename(mat_path)
if "_A1" in fname:
split = "train"
elif "_A2" in fname:
split = "val"
elif "_A3" in fname:
split = "test"
else:
return None # skip
return split, segs, labs
def main():
import argparse
args = argparse.ArgumentParser(description="Process EMG data from DB8.")
args.add_argument("--download_data", action="store_true")
args.add_argument("--data_dir", type=str, required=True)
args.add_argument("--save_dir", type=str, required=True)
args.add_argument(
"--window_size", type=int, help="Size of the sliding window for segmentation."
)
args.add_argument(
"--stride", type=int, help="Stride for the sliding window segmentation."
)
args.add_argument(
"--n_jobs", type=int, default=-1, help="Number of parallel jobs to run."
)
args = args.parse_args()
data_dir = args.data_dir # input folder with .mat files
os.makedirs(args.save_dir, exist_ok=True)
# download data if requested
if args.download_data:
# https://ninapro.hevs.ch/instructions/DB8.html
len_data = range(1, 13) # 1β12
base_url = "https://ninapro.hevs.ch/files/DB8/"
# download and unzip
for i in len_data:
url_a = f"{base_url}S{i}_E1_A1.mat"
url_b = f"{base_url}S{i}_E1_A2.mat"
url_c = f"{base_url}S{i}_E1_A3.mat"
os.system(f"wget -P {data_dir} {url_a}")
os.system(f"wget -P {data_dir} {url_b}")
os.system(f"wget -P {data_dir} {url_c}")
print(
f"Downloaded subject {i}\n{data_dir}/S{i}_E1_A1.mat and {data_dir}/S{i}_E1_A2.mat and {data_dir}/S{i}_E1_A3.mat"
)
sys.exit("Data downloaded and unzipped. Rerun without --download_data.")
fs = 2000.0 # Hz
# collect all .mat paths
mat_paths = [
os.path.join(args.data_dir, f)
for f in sorted(os.listdir(args.data_dir))
if f.endswith(".mat")
]
# run in parallel
results = Parallel(n_jobs=min(os.cpu_count(), args.n_jobs), verbose=5)(
delayed(process_mat_file)(mp, args.window_size, args.stride, fs)
for mp in mat_paths
)
# aggregate
splits = {k: {"data": [], "label": []} for k in ("train", "val", "test")}
for out in tqdm(results, desc="Processing files", unit="file"):
if out is None:
continue
split, segs, labs = out
splits[split]["data"].append(segs)
splits[split]["label"].append(labs)
# concatenate + save + stats
for split, d in tqdm(splits.items(), desc="Saving splits", unit="split"):
if not d["data"]:
continue
X = np.concatenate(d["data"], axis=0)
y = np.concatenate(d["label"], axis=0)
# transpose to [N, ch, window_size]
X = X.transpose(0, 2, 1)
print(f"Split: {split}, X shape: {X.shape}, y shape: {y.shape}")
# save
with h5py.File(os.path.join(args.save_dir, f"{split}.h5"), "w") as hf:
hf.create_dataset("data", data=X)
hf.create_dataset("label", data=y)
if __name__ == "__main__":
main()
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