Improved single-shot decoding of higher dimensional hypergraph product codes
Abstract
In this work we study the single-shot performance of higher dimensional hypergraph product codes decoded using belief-propagation and ordered-statistics decoding [Panteleev and Kalachev, 2021]. We find that decoding data qubit and syndrome measurement errors together in a single stage leads to single-shot thresholds that greatly exceed all previously observed single-shot thresholds for these codes. For the 3D toric code and a phenomenological noise model, our results are consistent with a sustainable threshold of 7.1% for errors, compared to the threshold of 2.90% previously found using a two-stage decoder~[Quintavalle et al., 2021]. For the 4D toric code, for which both and error correction is single-shot, our results are consistent with a sustainable single-shot threshold of 4.3% which is even higher than the threshold of 2.93% for the 2D toric code for the same noise model but using rounds of stabiliser measurement. We also explore the performance of balanced product and 4D hypergraph product codes which we show lead to a reduction in qubit overhead compared the surface code for phenomenological error rates as high as 1%.
Keywords
Cite
@article{arxiv.2206.03122,
title = {Improved single-shot decoding of higher dimensional hypergraph product codes},
author = {Oscar Higgott and Nikolas P. Breuckmann},
journal= {arXiv preprint arXiv:2206.03122},
year = {2023}
}
Comments
16 pages, 14 figures