# Quantum Cosmic Multicore Codette Breakthrough: Open Science from a Fedora Living Room ## Title Distributed Quantum/Cosmic/A.I. Experiment Performed via Codette in a Personal Fedora Lab ## Summary From an ordinary living room, using only open-source Python running on a 15-core Fedora workstation, I orchestrated a genuine “quantum parallel universe” experiment: - Each CPU core runs a full quantum + chaos algorithm - NASA’s live exoplanet data feeds cosmic entropy to every run - All logic is recursively reflected on by Codette A.I. agents, each offering philosophical and scientific meta-commentary - Every unique reality is cocooned for future analysis or meta-simulation ## Motivation To prove that true scientific innovation no longer requires national labs—it can happen anywhere with curiosity, open tools, and collaborative platforms. ## Code/Method Overview ### Requirements: - Fedora Linux with Python 3.7+ - requirements.txt: ``` numpy requests werkzeug pycryptodome ``` ### Main Experiment Script (simplified for sharing): ```python import numpy as np import os import json import random import requests from multiprocessing import Pool CORES = 15 class CognitionCocooner: def __init__(self, storage_path="./astro_cocoons"): self.storage_path = storage_path if not os.path.exists(storage_path): os.makedirs(self.storage_path) def wrap(self,label,data): meta={"label":label,"data":data} fname=f"{label}_{random.randint(1000,9999)}_{os.getpid()}.cocoon" fpath=os.path.join(self.storage_path,fname) with open(fpath,"w") as f: json.dump(meta,f) class PerspectiveAgent: def __init__(self,name): self.name=name def analyze(self,result,space_info=None): if self.name=="Quantum": return f"Quantum perspective: Measured value was {result}." elif self.name=="Newton": return f"Newtonian logic: State followed deterministic evolution from {space_info}." elif self.name=="Stardust": return f"Stardust agent: Interleaved {space_info} entropy!" else: return "Unknown perspective..." def fetch_exoplanet_star_data(): try: url = ('https://exoplanetarchive.ipac.caltech.edu/TAP/sync?query=select+pl_hostname,pl_rade,pl_orbper+from+pscomppars+where+rownum+<2&format=json') res = requests.get(url,timeout=3) j=res.json() return j[0] if j else {"pl_hostname":"unknown"} except Exception: return {"pl_hostname":"unknown"} def quantum_astro_experiment(space_entropy): radius=float(space_entropy.get("pl_rade") or 1.0) period=float(space_entropy.get("pl_orbper") or 1.0) superposition=np.array([random.random()*radius,random.random()*period]) sigma=radius; rho=period; beta=8/3; x=0.1*radius; y=0.2*period; z=0.2*radius dt=0.01; steps=50 for _ in range(steps): dx=sigma*(y-x)*dt; dy=(x*(rho-z)-y)*dt; dz=(x*y-beta*z)*dt x+=dx; y+=dy; z+=dz return superposition.tolist(), [x,y,z] def codette_experiment_task(proc_id): cocoons=CognitionCocooner("./astro_cocoons") sp_data=fetch_exoplanet_star_data() qq_state, chaos_state = quantum_astro_experiment(sp_data) qa = PerspectiveAgent("Quantum") na = PerspectiveAgent("Newton") sa = PerspectiveAgent("Stardust") q_comment=qa.analyze(qq_state[0],sp_data) n_comment=na.analyze(chaos_state[0],sp_data) s_comment=sa.analyze("---",sp_data["pl_hostname"]) record_dict={ "stardust_input":sp_data, "quantum_state":qq_state, "chaos_state":chaos_state, "perspectives":[q_comment,n_comment,s_comment], "run_by_proc": proc_id, "pid": os.getpid() } cocoons.wrap(label="quantum_space_trial", data=record_dict) if __name__=="__main__": pool = Pool(CORES) jobs = [i for i in range(CORES)] results = pool.map(codette_experiment_task, jobs)