Interactive quantum advantage with noisy, shallow Clifford circuits
Abstract
Recent work by Bravyi et al. constructs a relation problem that a noisy constant-depth quantum circuit (QNC) can solve with near certainty (probability ), but that any bounded fan-in constant-depth classical circuit (NC) fails with some constant probability. We show that this robustness to noise can be achieved in the other low-depth quantum/classical circuit separations in this area. In particular, we show a general strategy for adding noise tolerance to the interactive protocols of Grier and Schaeffer. As a consequence, we obtain an unconditional separation between noisy QNC circuits and AC circuits for all primes , and a conditional separation between noisy QNC circuits and log-space classical machines under a plausible complexity-theoretic conjecture. A key component of this reduction is showing average-case hardness for the classical simulation tasks -- that is, showing that a classical simulation of the quantum interactive task is still powerful even if it is allowed to err with constant probability over a uniformly random input. We show that is true even for quantum tasks which are L-hard to simulate. To do this, we borrow techniques from randomized encodings used in cryptography.
Cite
@article{arxiv.2102.06833,
title = {Interactive quantum advantage with noisy, shallow Clifford circuits},
author = {Daniel Grier and Nathan Ju and Luke Schaeffer},
journal= {arXiv preprint arXiv:2102.06833},
year = {2021}
}
Comments
33 pages (minor edits)