English

Tight Lower Bound for Approximating Parametrized Maximum Likelihood Decoding under ETH

Computational Complexity 2026-05-12 v1

Abstract

We present a simple deterministic reduction which, assuming the Exponential Time Hypothesis (ETH\mathsf{ETH}), yields tight lower bounds for approximating the parameterized Maximum Likelihood Decoding problem (MLD\mathsf{MLD}) and the parameterized Nearest Codeword Problem (NCP\mathsf{NCP}) within some fixed constant factor. Our starting point is the ETH-based exponential-time hardness of (c,s)(c,s)-Gap-MAXLIN\mathsf{MAXLIN} established in [BHI+24]. We transform a (c,s)(c,s)-Gap-MAXLIN\mathsf{MAXLIN} instance into an instance of γ\gamma-Gap kk-MLD\mathsf{MLD} via a novel combinatorial object that we call a cover family. We provide both a randomized construction of the required cover families and a subsequent derandomization. Prior to our work, nΩ(k)n^{\Omega(k)} hardness for constant-factor approximation was only shown under the randomized Gap Exponential Time Hypothesis Gap-ETH\mathsf{ETH} [Man20], which is a much stronger assumption than ETH\mathsf{ETH}. Under ETH\mathsf{ETH}, the strongest known lower bound was nΩ(k/polylogk)n^{\Omega(k/\operatorname{poly} \log k)} due to [BKM25]. Unlike previous approaches that rely on reductions from the hardness of approximating 22-CSP\mathsf{CSP}, our reduction provides a more direct and conceptually simpler route to achieving the optimal lower bounds.

Keywords

Cite

@article{arxiv.2605.08797,
  title  = {Tight Lower Bound for Approximating Parametrized Maximum Likelihood Decoding under ETH},
  author = {Rishav Gupta and Bingkai Lin and Xin Zheng},
  journal= {arXiv preprint arXiv:2605.08797},
  year   = {2026}
}
R2 v1 2026-07-01T12:59:42.105Z