English

Low-depth random Clifford circuits for quantum coding against Pauli noise using a tensor-network decoder

Quantum Physics 2024-07-18 v1

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 nn qubits, embedded in one spatial dimension (1D), have a logarithmic depth d=O(logn)d=\mathcal{O}(\log{n}). 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 d=O(n)d=\mathcal{O}(n)-depth random encoding circuits, can be attained even when the circuit depth is restricted to d=O(logn)d=\mathcal{O}(\log n) 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 log\log-depth encoding circuits in 1D.

Keywords

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}
}
R2 v1 2026-06-28T07:28:23.657Z