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divide-sixty3.py
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divide-sixty3.py
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from qiskit import QuantumCircuit, transpile
from qiskit_aer import AerSimulator
import numpy as np
def generate_and_split_circuit():
qc = QuantumCircuit(60)
# Apply some gates to the first 30 qubits
for i in range(30):
qc.h(i)
# Apply some gates to the second 30 qubits
for i in range(30, 60):
qc.h(i)
# Add some two-qubit gates between different parts of the circuit
for i in range(30):
qc.cx(i, i + 30)
qc.measure_all()
return qc
def split_into_subcircuits(qc):
# Create empty circuits for the two 30-qubit sections
qc1 = QuantumCircuit(30)
qc2 = QuantumCircuit(30)
# Copy operations from the first half of the original circuit
for instr, qargs, cargs in qc.data:
if all(q.index < 30 for q in qargs):
qc1.append(instr, qargs)
# Copy operations from the second half of the original circuit
for instr, qargs, cargs in qc.data:
if all(q.index >= 30 for q in qargs):
new_qargs = [q.index - 30 for q in qargs]
qc2.append(instr, new_qargs)
return qc1, qc2
def run_qiskit_simulation(qc):
# Use Qiskit's Aer simulator for local simulation
simulator = AerSimulator(method='statevector')
compiled_circuit = transpile(qc, simulator)
result = simulator.run(compiled_circuit).result()
statevector = result.get_statevector()
return statevector
def combine_results(statevector1, statevector2):
# Combine statevectors from both sub-circuits
combined_statevector = np.kron(statevector1, statevector2)
return combined_statevector
# Main
qc = generate_and_split_circuit()
qc1, qc2 = split_into_subcircuits(qc)
statevector1 = run_qiskit_simulation(qc1)
statevector2 = run_qiskit_simulation(qc2)
combined_statevector = combine_results(statevector1, statevector2)
print("Combined Statevector:", combined_statevector)