Google quantum computing framework. Use when targeting Google Quantum AI hardware, designing noise-aware circuits, or running quantum characterization experiments. Best for Google hardware, noise modeling, and low-level circuit design. For IBM hardware use qiskit; for quantum ML with autodiff use pennylane; for physics simulations use qutip.
cirq-google) or partner backends (IonQ, Azure Quantum, AQT, Pasqal)uv pip install "cirq==1.6.1"
# Google Quantum Engine (requires approved GCP project access)
uv pip install "cirq-google==1.6.1"
# IonQ
uv pip install "cirq-ionq==1.6.1"
# AQT (Alpine Quantum Technologies)
uv pip install "cirq-aqt==1.6.1"
# Pasqal
uv pip install "cirq-pasqal==1.6.1"
# Azure Quantum (IonQ, Honeywell/Quantinuum backends)
uv pip install "azure-quantum[cirq]"
import cirq
import numpy as np
# Create qubits
q0, q1 = cirq.LineQubit.range(2)
# Build circuit
circuit = cirq.Circuit(
cirq.H(q0), # Hadamard on q0
cirq.CNOT(q0, q1), # CNOT with q0 control, q1 target
cirq.measure(q0, q1, key='result')
)
print(circuit)
# Simulate
simulator = cirq.Simulator()
result = simulator.run(circuit, repetitions=1000)
# Display results
print(result.histogram(key='result'))
import sympy
# Define symbolic parameter
theta = sympy.Symbol('theta')
# Create parameterized circuit
circuit = cirq.Circuit(
cirq.ry(theta)(q0),
cirq.measure(q0, key='m')
)
# Sweep over parameter values
sweep = cirq.Linspace('theta', start=0, stop=2*np.pi, length=20)
results = simulator.run_sweep(circuit, params=sweep, repetitions=1000)
# Process results
for params, result in zip(sweep, results):
theta_val = params['theta']
counts = result.histogram(key='m')
print(f"θ={theta_val:.2f}: {counts}")
cirq-google) — Sycamore, Weber, Willow processors via Quantum Engine (restricted access; requires approved GCP project)cirq-ionq) — trapped-ion QPUs and simulatorsazure-quantum[cirq]) — IonQ and Honeywell/Quantinuum backendscirq-aqt) — Alpine Quantum Technologiescirq-pasqal) — neutral-atom devicesimport scipy.optimize
def variational_algorithm(ansatz, cost_function, initial_params):
"""Template for variational quantum algorithms."""
def objective(params):
circuit = ansatz(params)
simulator = cirq.Simulator()
result = simulator.simulate(circuit)
return cost_function(result)
# Optimize
result = scipy.optimize.minimize(
objective,
initial_params,
method='COBYLA'
)
return result
# Define ansatz
def my_ansatz(params):
q = cirq.LineQubit(0)
return cirq.Circuit(
cirq.ry(params[0])(q),
cirq.rz(params[1])(q)
)
# Define cost function
def my_cost(result):
state = result.final_state_vector
# Calculate cost based on state
return np.real(state[0])
# Run optimization
result = variational_algorithm(my_ansatz, my_cost, [0.0, 0.0])
import os
def run_on_hardware(circuit, provider='google', processor_id=None, repetitions=1000):
"""Template for running on quantum hardware."""
if provider == 'google':
import cirq_google as cg
project_id = os.environ['GOOGLE_CLOUD_PROJECT']
engine = cg.Engine(project_id=project_id)
# List available processors: engine.list_processors()
processor_id = processor_id or 'weber' # use your assigned processor_id
sampler = engine.get_sampler(processor_id=processor_id)
return sampler.run(circuit, repetitions=repetitions)
elif provider == 'ionq':
import cirq_ionq as ionq
# Requires IONQ_API_KEY in environment
service = ionq.Service()
return service.run(circuit, repetitions=repetitions, target='qpu')
elif provider == 'azure':
from azure.quantum.cirq import AzureQuantumService
service = AzureQuantumService(
resource_id=os.environ['AZURE_QUANTUM_RESOURCE_ID'],
location=os.environ['AZURE_QUANTUM_LOCATION'],
)
return service.run(circuit, repetitions=repetitions, target='ionq.qpu')
else:
raise ValueError(f"Unknown provider: {provider}")
def noise_comparison_study(circuit, noise_levels):
"""Compare circuit performance at different noise levels."""
results = {}
for noise_level in noise_levels:
# Create noisy circuit
noisy_circuit = circuit.with_noise(cirq.depolarize(p=noise_level))
# Simulate
simulator = cirq.DensityMatrixSimulator()
result = simulator.run(noisy_circuit, repetitions=1000)
# Analyze
results[noise_level] = {
'histogram': result.histogram(key='result'),
'dominant_state': max(
result.histogram(key='result').items(),
key=lambda x: x[1]
)
}
return results
# Run study
noise_levels = [0.0, 0.001, 0.01, 0.05, 0.1]
results = noise_comparison_study(circuit, noise_levels)
transformation.md for optimization techniqueshardware.md for device-specific compilationsimulation.md for performance optimization