pennylane
Hardware-agnostic quantum ML framework with automatic differentiation. Use when training quantum circuits via gradients, building hybrid quantum-classical models, or needing device portability across IBM/Google/Rigetti/IonQ. Best for variational algorithms (VQE, QAOA), quantum neural networks, and integration with PyTorch or JAX. For hardware-specific optimizations use qiskit (IBM) or cirq (Google); for open quantum systems use qutip.
How do I install this agent skill?
npx skills add https://github.com/k-dense-ai/scientific-agent-skills --skill pennylaneIs this agent skill safe to install?
- Gen Agent Trust Hubpass
The PennyLane skill is a comprehensive documentation and code resource for quantum machine learning and chemistry. It utilizes standard industry libraries and follows best practices for quantum programming without any security risks detected.
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No alerts
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Risk: LOW · No issues
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Score: 93/100 · 2 sections analyzed
What does this agent skill do?
PennyLane
Overview
PennyLane is a quantum computing library that enables training quantum computers like neural networks. It provides automatic differentiation of quantum circuits, device-independent programming, and seamless integration with classical machine learning frameworks.
Installation
PennyLane 0.45.0 requires Python 3.11 or newer. Install using uv with pinned versions for reproducible environments:
uv pip install "pennylane==0.45.0"
For quantum hardware access, install the plugin matching the target provider. Start from a clean environment when adding or upgrading Qiskit because its dependency graph is strict.
# IBM Quantum
uv pip install "pennylane-qiskit==0.45.0"
# Amazon Braket
uv pip install "amazon-braket-pennylane-plugin==1.34.1"
# Google Cirq
uv pip install "pennylane-cirq==0.44.0"
# Rigetti Forest
uv pip install "pennylane-rigetti==0.40.0"
# IonQ
uv pip install "pennylane-ionq==0.45.0"
# High-performance local simulators
uv pip install "pennylane-lightning==0.45.0"
# Catalyst JIT compilation
uv pip install "pennylane-catalyst==0.15.0"
Quick Start
Build a quantum circuit and optimize its parameters:
import pennylane as qml
from pennylane import numpy as np
# Create device
dev = qml.device('default.qubit', wires=2)
# Define quantum circuit
@qml.qnode(dev)
def circuit(params):
qml.RX(params[0], wires=0)
qml.RY(params[1], wires=1)
qml.CNOT(wires=[0, 1])
return qml.expval(qml.PauliZ(0))
# Optimize parameters
opt = qml.GradientDescentOptimizer(stepsize=0.1)
params = np.array([0.1, 0.2], requires_grad=True)
for i in range(100):
params = opt.step(circuit, params)
Core Capabilities
1. Quantum Circuit Construction
Build circuits with gates, measurements, and state preparation. See references/quantum_circuits.md for:
- Single and multi-qubit gates
- Controlled operations and conditional logic
- Mid-circuit measurements and adaptive circuits
- Various measurement types (expectation, probability, samples)
- Circuit inspection and debugging
2. Quantum Machine Learning
Create hybrid quantum-classical models. See references/quantum_ml.md for:
- Integration with PyTorch and JAX
- Quantum neural networks and variational classifiers
- Data encoding strategies (angle, amplitude, basis, IQP)
- Training hybrid models with backpropagation
- Transfer learning with quantum circuits
3. Quantum Chemistry
Simulate molecules and compute ground state energies. See references/quantum_chemistry.md for:
- Molecular Hamiltonian generation
- Variational Quantum Eigensolver (VQE)
- UCCSD ansatz for chemistry
- Geometry optimization and dissociation curves
- Molecular property calculations
4. Device Management
Execute on simulators or quantum hardware. See references/devices_backends.md for:
- Built-in simulators (default.qubit, lightning.qubit, default.mixed)
- Hardware plugins (IBM, Amazon Braket, Google, Rigetti, IonQ)
- Device selection and configuration
- Performance optimization and caching
- GPU acceleration and JIT compilation
5. Optimization
Train quantum circuits with various optimizers. See references/optimization.md for:
- Built-in optimizers (Adam, gradient descent, momentum, RMSProp)
- Gradient computation methods (backprop, parameter-shift, adjoint)
- Variational algorithms (VQE, QAOA)
- Training strategies (learning rate schedules, mini-batches)
- Handling barren plateaus and local minima
6. Advanced Features
Leverage templates, transforms, and compilation. See references/advanced_features.md for:
- Circuit templates and layers
- Transforms and circuit optimization
- Pulse-level programming
- Catalyst JIT compilation
- Noise models and error mitigation
- Resource estimation
Common Workflows
Train a Variational Classifier
# 1. Define ansatz
@qml.qnode(dev)
def classifier(x, weights):
# Encode data
qml.AngleEmbedding(x, wires=range(4))
# Variational layers
qml.StronglyEntanglingLayers(weights, wires=range(4))
return qml.expval(qml.PauliZ(0))
# 2. Train
opt = qml.AdamOptimizer(stepsize=0.01)
weights = np.random.random((3, 4, 3)) # 3 layers, 4 wires
for epoch in range(100):
for x, y in zip(X_train, y_train):
weights = opt.step(lambda w: (classifier(x, w) - y)**2, weights)
Run VQE for Molecular Ground State
from pennylane import qchem
# 1. Build Hamiltonian
symbols = ['H', 'H']
geometry = np.array([[0.0, 0.0, -0.66140414], [0.0, 0.0, 0.66140414]])
molecule = qchem.Molecule(symbols, geometry)
H, n_qubits = qchem.molecular_hamiltonian(molecule)
hf_state = qchem.hf_state(electrons=2, orbitals=n_qubits)
singles, doubles = qchem.excitations(electrons=2, orbitals=n_qubits)
s_wires, d_wires = qchem.excitations_to_wires(singles, doubles)
# 2. Define ansatz
@qml.qnode(dev)
def vqe_circuit(params):
qml.BasisState(hf_state, wires=range(n_qubits))
qml.UCCSD(params, wires=range(n_qubits), s_wires=s_wires, d_wires=d_wires)
return qml.expval(H)
# 3. Optimize
opt = qml.AdamOptimizer(stepsize=0.1)
params = np.zeros(len(singles) + len(doubles), requires_grad=True)
for i in range(100):
params, energy = opt.step_and_cost(vqe_circuit, params)
print(f"Step {i}: Energy = {energy:.6f} Ha")
Switch Between Devices
# Same circuit, different backends
circuit_def = lambda dev: qml.qnode(dev)(circuit_function)
# Test on simulator
dev_sim = qml.device('default.qubit', wires=4)
result_sim = circuit_def(dev_sim)(params)
# Run on quantum hardware
from qiskit_ibm_runtime import QiskitRuntimeService
service = QiskitRuntimeService()
backend = service.least_busy(operational=True, simulator=False, min_num_qubits=4)
dev_hw = qml.device('qiskit.remote', wires=backend.num_qubits, backend=backend)
result_hw = circuit_def(dev_hw)(params)
Detailed Documentation
For comprehensive coverage of specific topics, consult the reference files:
- Getting started:
references/getting_started.md- Installation, basic concepts, first steps - Quantum circuits:
references/quantum_circuits.md- Gates, measurements, circuit patterns - Quantum ML:
references/quantum_ml.md- Hybrid models, framework integration, QNNs - Quantum chemistry:
references/quantum_chemistry.md- VQE, molecular Hamiltonians, chemistry workflows - Devices:
references/devices_backends.md- Simulators, hardware plugins, device configuration - Optimization:
references/optimization.md- Optimizers, gradients, variational algorithms - Advanced:
references/advanced_features.md- Templates, transforms, JIT compilation, noise
Best Practices
- Start with simulators - Test on
default.qubitbefore deploying to hardware - Use parameter-shift for hardware - Backpropagation only works on simulators
- Choose appropriate encodings - Match data encoding to problem structure
- Initialize carefully - Use small random values to avoid barren plateaus
- Monitor gradients - Check for vanishing gradients in deep circuits
- Cache devices - Reuse device objects to reduce initialization overhead
- Profile circuits - Use
qml.specs()to analyze circuit complexity - Test locally - Validate on simulators before submitting to hardware
- Use templates - Leverage built-in templates for common circuit patterns
- Compile when possible - Use Catalyst JIT for performance-critical code
Resources
- Official documentation: https://docs.pennylane.ai
- Codebook (tutorials): https://pennylane.ai/codebook
- QML demonstrations: https://pennylane.ai/qml/demonstrations
- Community forum: https://discuss.pennylane.ai
- GitHub: https://github.com/PennyLaneAI/pennylane
How can the creator link this skill?
Add the canonical catalog link to the repository README so users can inspect current installs and available audits. The publishing guide covers the complete discovery path.
<a href="https://skillzs.dev/skills/k-dense-ai/scientific-agent-skills/pennylane">View pennylane on skillZs</a>