With TensorNetwork project announced by Google, quantum circuit simulator based on it may gain benefits from swift implementation to auto differentiation abilities.
See tensorcircuit.applications for relevant code on so-call differentiable quantum architecture search.
import tensorcircuit as tc
c = tc.Circuit(2)
c.H(0)
c.CNOT(0,1)
print(c.perfect_sampling())
print(c.wavefunction())
print(c.measure(1))
print(c.expectation((tc.gates.z(), [1])))Runtime behavior changing:
tc.set_backend("tensorflow")
tc.set_dtype("complex128")
tc.set_contractor("greedy")Auto differentiations with jit (tf and jax supported):
@tc.backend.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(), [0])))
g = tc.backend.grad(forward)
g = tc.backend.jit(g)
theta = tc.gates.num_to_tensor(1.0)
print(g(theta))For application of Differentiable Quantum Architecture Search, see applications. Reference paper: https://arxiv.org/pdf/2010.08561.pdf.
For application of Variational Quantum-Neural Hybrid Eigensolver, see applications. Reference paper: https://arxiv.org/pdf/2106.05105.pdf.