English

Noisy decoding by shallow circuits with parities: classical and quantum

Computational Complexity 2024-01-25 v2 Combinatorics Quantum Physics

Abstract

We consider the problem of decoding corrupted error correcting codes with NC0[]^0[\oplus] circuits in the classical and quantum settings. We show that any such classical circuit can correctly recover only a vanishingly small fraction of messages, if the codewords are sent over a noisy channel with positive error rate. Previously this was known only for linear codes with large dual distance, whereas our result applies to any code. By contrast, we give a simple quantum circuit that correctly decodes the Hadamard code with probability Ω(ε2)\Omega(\varepsilon^2) even if a (1/2ε)(1/2 - \varepsilon)-fraction of a codeword is adversarially corrupted. Our classical hardness result is based on an equidistribution phenomenon for multivariate polynomials over a finite field under biased input-distributions. This is proved using a structure-versus-randomness strategy based on a new notion of rank for high-dimensional polynomial maps that may be of independent interest. Our quantum circuit is inspired by a non-local version of the Bernstein-Vazirani problem, a technique to generate ``poor man's cat states'' by Watts et al., and a constant-depth quantum circuit for the OR function by Takahashi and Tani.

Keywords

Cite

@article{arxiv.2302.02870,
  title  = {Noisy decoding by shallow circuits with parities: classical and quantum},
  author = {Jop Briët and Harry Buhrman and Davi Castro-Silva and Niels M. P. Neumann},
  journal= {arXiv preprint arXiv:2302.02870},
  year   = {2024}
}

Comments

39 pages; This is the full version of an extended abstract that will appear in the proceedings of ITCS'24

R2 v1 2026-06-28T08:33:08.451Z