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Numerical study of hypergraph product codes

Quantum Physics 2019-05-03 v2

Abstract

Hypergraph product codes introduced by Tillich and Z\'emor are a class of quantum LDPC codes with constant rate and distance scaling with the square-root of the block size. Quantum expander codes, a subclass of these codes, can be decoded using the linear time small-set-flip algorithm of Leverrier, Tillich and Z\'emor. In this paper, we numerically estimate the performance for the hypergraph product codes under independent bit and phase flip noise. We focus on two families of hypergraph product codes. The first family has rate 1/611.6%1/61 \sim 1.6\%, has qubits of weight 1010 or 1212 and stabilizers of weight 1111. We report a threshold near 4.6%4.6\% for the small-set-flip decoder. We also show that for similar rate, the performance of the hypergraph product is better than the performance of the toric code as soon as we deal with more than 500500 logical qubits and that for 36003600 logical qubits, the logical error rate for the hypergraph product code is several orders of magnitude smaller. The second family has rate 0.20.2, qubits of weight 1010 and 2020 and stabilizers of weight 1515. We report a threshold near 2%2\% for the small-set-flip decoder.

Keywords

Cite

@article{arxiv.1810.03681,
  title  = {Numerical study of hypergraph product codes},
  author = {Antoine Grospellier and Anirudh Krishna},
  journal= {arXiv preprint arXiv:1810.03681},
  year   = {2019}
}

Comments

11 pages, 3 figures; Updated to include improved plots and new code family

R2 v1 2026-06-23T04:32:41.724Z