English

Explicit Almost-Optimal $\varepsilon$-Balanced Codes via Free Expander Walks

Computational Complexity 2026-04-09 v2 Discrete Mathematics Data Structures and Algorithms Combinatorics

Abstract

We study the problem of constructing explicit codes whose rate and distance match the Gilbert-Varshamov bound in the low-rate, high-distance regime. In 2017, Ta-Shma gave an explicit family of codes where every pair of codewords has relative distance 1ε2\frac{1-\varepsilon}{2}, with rate Ω(ε2+o(1))\Omega(\varepsilon^{2+o(1)}), matching the Gilbert-Varshamov bound up to a factor of εo(1)\varepsilon^{o(1)}. Ta-Shma's construction was based on starting with a good code and amplifying its bias with walks arising from the ss-wide-replacement product. In this work, we give a simpler almost-optimal construction, based on what we call free expander walks: ordinary expander walks where each step is taken on a distinct expander from a carefully chosen sequence. This sequence of expanders is derived from the construction of near-XX-Ramanujan graphs due to O'Donnell and Wu. We additionally discuss some additional applications of near-XX-Ramanujan graphs to "on average" lossless expansion and rotating expanders.

Cite

@article{arxiv.2601.12606,
  title  = {Explicit Almost-Optimal $\varepsilon$-Balanced Codes via Free Expander Walks},
  author = {Jun-Ting Hsieh and Sidhanth Mohanty and Rachel Yun Zhang},
  journal= {arXiv preprint arXiv:2601.12606},
  year   = {2026}
}

Comments

15 pages

R2 v1 2026-07-01T09:09:48.770Z