Solving the sampling problem of the Sycamore quantum circuits
Abstract
We study the problem of generating independent samples from the output distribution of Google's Sycamore quantum circuits with a target fidelity, which is believed to be beyond the reach of classical supercomputers and has been used to demonstrate quantum supremacy. We propose a new method to classically solve this problem by contracting the corresponding tensor network just once, and is massively more efficient than existing methods in obtaining a large number of uncorrelated samples with a target fidelity. For the Sycamore quantum supremacy circuit with qubits and cycles, we have generated one million uncorrelated bitstrings which are sampled from a distribution , where the approximate state has fidelity . The whole computation has cost about hours on a computational cluster with GPUs. The obtained one million samples, the contraction code and contraction order is made public. If our algorithm could be implemented with high efficiency on a modern supercomputer with ExaFLOPS performance, we estimate that ideally, the simulation would cost a few dozens of seconds, which is faster than Google's quantum hardware.
Cite
@article{arxiv.2111.03011,
title = {Solving the sampling problem of the Sycamore quantum circuits},
author = {Feng Pan and Keyang Chen and Pan Zhang},
journal= {arXiv preprint arXiv:2111.03011},
year = {2022}
}
Comments
17 pages, 13 figures