English

Improved Lower Bounds for Approximating Parameterized Nearest Codeword and Related Problems under ETH

Computational Complexity 2024-02-16 v1

Abstract

In this paper we present a new gap-creating randomized self-reduction for parameterized Maximum Likelihood Decoding problem over Fp\mathbb{F}_p (kk-MLDp_p). The reduction takes a kk-MLDp_p instance with knk\cdot n vectors as input, runs in time f(k)nO(1)f(k)n^{O(1)} for some computable function ff, outputs a (3/2ε)(3/2-\varepsilon)-Gap-kk'-MLDp_p instance for any ε>0\varepsilon>0, where k=O(k2logk)k'=O(k^2\log k). Using this reduction, we show that assuming the randomized Exponential Time Hypothesis (ETH), no algorithms can approximate kk-MLDp_p (and therefore its dual problem kk-NCPp_p) within factor (3/2ε)(3/2-\varepsilon) in f(k)no(k/logk)f(k)\cdot n^{o(\sqrt{k/\log k})} time for any ε>0\varepsilon>0. We then use reduction by Bhattacharyya, Ghoshal, Karthik and Manurangsi (ICALP 2018) to amplify the (3/2ε)(3/2-\varepsilon)-gap to any constant. As a result, we show that assuming ETH, no algorithms can approximate kk-NCPp_p and kk-MDPp_p within γ\gamma-factor in f(k)no(kεγ)f(k)n^{o(k^{\varepsilon_\gamma})} time for some constant εγ>0\varepsilon_\gamma>0. Combining with the gap-preserving reduction by Bennett, Cheraghchi, Guruswami and Ribeiro (STOC 2023), we also obtain similar lower bounds for kk-MDPp_p, kk-CVPp_p and kk-SVPp_p. These results improve upon the previous f(k)nΩ(polylogk)f(k)n^{\Omega(\mathsf{poly} \log k)} lower bounds for these problems under ETH using reductions by Bhattacharyya et al. (J.ACM 2021) and Bennett et al. (STOC 2023).

Keywords

Cite

@article{arxiv.2402.09825,
  title  = {Improved Lower Bounds for Approximating Parameterized Nearest Codeword and Related Problems under ETH},
  author = {Shuangle Li and Bingkai Lin and Yuwei Liu},
  journal= {arXiv preprint arXiv:2402.09825},
  year   = {2024}
}

Comments

32 pages, 3 figures

R2 v1 2026-06-28T14:49:24.751Z