Low-depth random Clifford circuits for quantum coding against Pauli noise using a tensor-network decoder
Abstract
Recent work [M. J. Gullans et al., Physical Review X, 11(3):031066 (2021)] has shown that quantum error correcting codes defined by random Clifford encoding circuits can achieve a non-zero encoding rate in correcting errors even if the random circuits on qubits, embedded in one spatial dimension (1D), have a logarithmic depth . However, this was demonstrated only for a simple erasure noise model. In this work, we discover that this desired property indeed holds for the conventional Pauli noise model. Specifically, we numerically demonstrate that the hashing bound, i.e., a rate known to be achieved with -depth random encoding circuits, can be attained even when the circuit depth is restricted to in 1D for depolarizing noise of various strengths. This analysis is made possible with our development of a tensor-network maximum-likelihood decoding algorithm that works efficiently for -depth encoding circuits in 1D.
Cite
@article{arxiv.2212.05071,
title = {Low-depth random Clifford circuits for quantum coding against Pauli noise using a tensor-network decoder},
author = {Andrew S. Darmawan and Yoshifumi Nakata and Shiro Tamiya and Hayata Yamasaki},
journal= {arXiv preprint arXiv:2212.05071},
year = {2024}
}