Quantum circuits on top of tensor network
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TensorCircuit is the next generation of quantum circuit simulators with support for automatic differentiation, just-in-time compiling, hardware acceleration, and vectorized parallelism.
TensorCircuit is built on top of modern machine learning frameworks and is machine learning backend agnostic. It is specifically suitable for highly efficient simulations of quantum-classical hybrid paradigm and variational quantum algorithms.
The following are some minimal demos.
- Circuit manipulation:
import tensorcircuit as tc c = tc.Circuit(2) c.H(0) c.CNOT(0,1) c.rx(1, theta=0.2) print(c.wavefunction()) print(c.expectation_ps(z=[0, 1])) print(c.sample())
- Runtime behavior customization:
tc.set_backend("tensorflow") tc.set_dtype("complex128") tc.set_contractor("greedy")
- Automatic differentiations with jit:
def forward(theta): c = tc.Circuit(2) c.R(0, theta=theta, alpha=0.5, phi=0.8) return tc.backend.real(c.expectation((tc.gates.z(), ))) g = tc.backend.grad(forward) g = tc.backend.jit(g) theta = tc.array_to_tensor(1.0) print(g(theta))
The package is purely written in Python and can be obtained via pip as:
pip install tensorcircuit
We also have Docker support.
Tensor network simulation engine based
JIT, AD, vectorized parallelism compatible, GPU support
Time: 10 to 10^6 times acceleration compared to tfq or qiskit
Space: 600+ qubits 1D VQE workflow (converged energy inaccuracy: < 1%)
Flexibility: customized contraction, multiple ML backend/interface choices, multiple dtype precisions
API design: quantum for humans, less code, more power
For contribution guidelines and notes, see CONTRIBUTING.
We welcome issues, PRs, and discussions from everyone, and these are all hosted on GitHub.
Researches and Applications
VQEX - MBL
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