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Temukan potongan secara otomatis

Langkah 1: Peta

Buat Circuit dan observable

# Added by doQumentation — required packages for this notebook
!pip install -q numpy qiskit qiskit-addon-cutting
import numpy as np
from qiskit.circuit.random import random_circuit
from qiskit.quantum_info import SparsePauliOp

circuit = random_circuit(7, 6, max_operands=2, seed=1242)
observable = SparsePauliOp(["ZIIIIII", "IIIZIII", "IIIIIIZ"])

circuit.draw("mpl", scale=0.8)

Diagram Circuit kuantum

Langkah 2: Optimalkan

Temukan lokasi potongan, dengan maksimum 4 qubit per subcircuit. Circuit ini bisa dipisah menjadi dua dengan satu wire cut dan memotong satu CRZGate

from qiskit_addon_cutting.automated_cut_finding import (
find_cuts,
OptimizationParameters,
DeviceConstraints,
)

# Specify settings for the cut-finding optimizer
optimization_settings = OptimizationParameters(seed=111)

# Specify the size of the QPUs available
device_constraints = DeviceConstraints(qubits_per_subcircuit=4)

cut_circuit, metadata = find_cuts(circuit, optimization_settings, device_constraints)
print(
f'Found solution using {len(metadata["cuts"])} cuts with a sampling '
f'overhead of {metadata["sampling_overhead"]}.\n'
f'Lowest cost solution found: {metadata["minimum_reached"]}.'
)
for cut in metadata["cuts"]:
print(f"{cut[0]} at circuit instruction index {cut[1]}")
cut_circuit.draw("mpl", scale=0.8, fold=-1)
Found solution using 2 cuts with a sampling overhead of 127.06026169907257.
Lowest cost solution found: True.
Wire Cut at circuit instruction index 19
Gate Cut at circuit instruction index 28

Diagram Circuit kuantum

Tambahkan ancilla untuk wire cut dan perluas observable agar mencakup qubit ancilla

from qiskit_addon_cutting import cut_wires, expand_observables

qc_w_ancilla = cut_wires(cut_circuit)
observables_expanded = expand_observables(observable.paulis, circuit, qc_w_ancilla)
qc_w_ancilla.draw("mpl", scale=0.8, fold=-1)

Diagram Circuit kuantum

Partisi Circuit dan observable menjadi subcircuit dan subobservable. Hitung sampling overhead yang ditimbulkan dari pemotongan Gate dan wire ini.

from qiskit_addon_cutting import partition_problem

partitioned_problem = partition_problem(
circuit=qc_w_ancilla, observables=observables_expanded
)
subcircuits = partitioned_problem.subcircuits
subobservables = partitioned_problem.subobservables
print(
f"Sampling overhead: {np.prod([basis.overhead for basis in partitioned_problem.bases])}"
)
Sampling overhead: 127.06026169907257
subobservables
{0: PauliList(['IIII', 'IZII', 'IIIZ']),
1: PauliList(['ZIII', 'IIII', 'IIII'])}
subcircuits[0].draw("mpl", style="iqp", scale=0.8)

Diagram Circuit kuantum

subcircuits[1].draw("mpl", style="iqp", scale=0.8)

Diagram Circuit kuantum

Buat eksperimen untuk dijalankan di Backend.

from qiskit_addon_cutting import generate_cutting_experiments

subexperiments, coefficients = generate_cutting_experiments(
circuits=subcircuits, observables=subobservables, num_samples=1_000
)
print(
f"{len(subexperiments[0]) + len(subexperiments[1])} total subexperiments to run on backend."
)
96 total subexperiments to run on backend.

Langkah 3 dan 4 dari pola Qiskit kemudian bisa dilakukan seperti pada tutorial sebelumnya.