The computational power of real-world quantum computers is limited by errors.
When using quantum computers to perform algorithms which cannot be efficiently
simulated classically, it is important to quantify the accuracy with which the
computation has been performed. In this work we introduce a
machine-learning-based technique to estimate the fidelity between the state
produced by a noisy quantum circuit and the target state corresponding to ideal
noise-free computation. Our machine learning model is trained in a supervised
manner, using smaller or simpler circuits for which the fidelity can be
estimated using other techniques like direct fidelity estimation and quantum
state tomography. We demonstrate that, for simulated random quantum circuits
with a realistic noise model, the trained model can predict the fidelities of
more complicated circuits for which such methods are infeasible. In particular,
we show the trained model may make predictions for circuits with higher degrees
of entanglement than were available in the training set, and that the model may
make predictions for non-Clifford circuits even when the training set included
only Clifford-reducible circuits. This empirical demonstration suggests
classical machine learning may be useful for making predictions about
beyond-classical quantum circuits for some non-trivial problems.Comment: 27 pages, 6 figure