Cirq - Quantum Computing with Python
Cirq is Google Quantum AI's open-source framework for designing, simulating, and running quantum circuits on quantum computers and simulators.
When to Use This Skill
Use this skill when:
- Building, simulating, or optimizing NISQ circuits in Python
- Running jobs on Google Quantum AI processors (via
cirq-google) or partner backends (IonQ, Azure Quantum, AQT, Pasqal) - Modeling noise, compiling to hardware gatesets, or designing characterization experiments
- Using parameter sweeps, transformers, or the ReCirq experiment patterns
For IBM hardware use qiskit; for quantum ML with autodiff use pennylane; for physics simulations use qutip.
Installation
Requires Python 3.11+. Current stable release: 1.6.1 (August 2025). Vendor packages share the same version number.
uv pip install "cirq==1.6.1"
For hardware integration (pin matching versions for reproducibility):
# 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]"
For latest features during development, omit version pins; for production or hardware runs, pin all packages to the same Cirq release.
Quick Start
Basic Circuit
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'))
Parameterized Circuit
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}")
Core Capabilities
Circuit Building
For comprehensive information about building quantum circuits, including qubits, gates, operations, custom gates, and circuit patterns, see:
- references/building.md - Complete guide to circuit construction
Common topics:
- Qubit types (GridQubit, LineQubit, NamedQubit)
- Single and two-qubit gates
- Parameterized gates and operations
- Custom gate decomposition
- Circuit organization with moments
- Standard circuit patterns (Bell states, GHZ, QFT)
- Import/export (OpenQASM, JSON)
- Working with qudits and observables
Simulation
For detailed information about simulating quantum circuits, including exact simulation, noisy simulation, parameter sweeps, and the Quantum Virtual Machine, see:
- references/simulation.md - Complete guide to quantum simulation
Common topics:
- Exact simulation (state vector, density matrix)
- Sampling and measurements
- Parameter sweeps (single and multiple parameters)
- Noisy simulation
- State histograms and visualization
- Quantum Virtual Machine (QVM)
- Expectation values and observables
- Performance optimization
Circuit Transformation
For information about optimizing, compiling, and manipulating quantum circuits, see:
- references/transformation.md - Complete guide to circuit transformations
Common topics:
- Transformer framework
- Gate decomposition
- Circuit optimization (merge gates, eject Z gates, drop negligible operations)
- Circuit compilation for hardware
- Qubit routing and SWAP insertion
- Custom transformers
- Transformation pipelines
Hardware Integration
For information about running circuits on real quantum hardware from various providers, see:
- references/hardware.md - Complete guide to hardware integration
Supported providers:
- Google Quantum AI (
cirq-google) — Sycamore, Weber, Willow processors via Quantum Engine (restricted access; requires approved GCP project) - IonQ (
cirq-ionq) — trapped-ion QPUs and simulators - Azure Quantum (
azure-quantum[cirq]) — IonQ and Honeywell/Quantinuum backends - AQT (
cirq-aqt) — Alpine Quantum Technologies - Pasqal (
cirq-pasqal) — neutral-atom devices
Topics include device representation, qubit selection, authentication, job management, and circuit optimization for hardware. See Access and authentication for Google Cloud setup.
Noise Modeling
For information about modeling noise, noisy simulation, characterization, and error mitigation, see:
- references/noise.md - Complete guide to noise modeling
Common topics:
- Noise channels (depolarizing, amplitude damping, phase damping)
- Noise models (constant, gate-specific, qubit-specific, thermal)
- Adding noise to circuits
- Readout noise
- Noise characterization (randomized benchmarking, XEB)
- Noise visualization (heatmaps)
- Error mitigation techniques
Quantum Experiments
For information about designing experiments, parameter sweeps, data collection, and using the ReCirq framework, see:
- references/experiments.md - Complete guide to quantum experiments
Common topics:
- Experiment design patterns
- Parameter sweeps and data collection
- ReCirq framework structure
- Common algorithms (VQE, QAOA, QPE)
- Data analysis and visualization
- Statistical analysis and fidelity estimation
- Parallel data collection
Common Patterns
Variational Algorithm Template
import 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])
Hardware Execution Template
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_R