Improved Lower Bounds for all Odd-Query Locally Decodable Codes
Abstract
We prove that for every odd , any -query binary, possibly non-linear locally decodable code (-LDC) must satisfy . For even , this bound was established in a sequence of prior works. For , the above bound was achieved in a recent work of Alrabiah, Guruswami, Kothari and Manohar using an argument that crucially exploits known exponential lower bounds for -LDCs. Their strategy hits an inherent bottleneck for . Our key insight is identifying a general sufficient condition on the hypergraph of local decoding sets called -approximate strong regularity. This condition demands that 1) the number of hyperedges containing any given subset of vertices of size (i.e., its co-degree) be equal to the same but arbitrary value up to a multiplicative constant slack, and 2) all other co-degrees be upper-bounded relative to . This condition significantly generalizes related proposals in prior works that demand absolute upper bounds on all co-degrees. We give an argument based on spectral bounds on Kikuchi Matrices that lower bounds the blocklength of any LDC whose local decoding sets satisfy -approximate strong regularity for any . Crucially, unlike prior works, our argument works despite having no non-trivial absolute upper bound on the co-degrees of any set of vertices. To apply our argument to arbitrary -LDCs, we give a new, greedy, approximate strong regularity decomposition that shows that arbitrary, dense enough hypergraphs can be partitioned (up to a small error) into approximately strongly regular pieces satisfying the required relative bounds on the co-degrees.
Cite
@article{arxiv.2411.14361,
title = {Improved Lower Bounds for all Odd-Query Locally Decodable Codes},
author = {Arpon Basu and Jun-Ting Hsieh and Pravesh K. Kothari and Andrew D. Lin},
journal= {arXiv preprint arXiv:2411.14361},
year = {2024}
}