English

An Exponential Lower Bound for Linear 3-Query Locally Correctable Codes

Computational Complexity 2023-11-02 v1

Abstract

We prove that the blocklength nn of a linear 33-query locally correctable code (LCC) L ⁣:FkFn\mathcal{L} \colon {\mathbb F}^k \to {\mathbb F}^n with distance δ\delta must be at least n2Ω((δ2k(F1)2)1/8)n \geq 2^{\Omega\left(\left(\frac{\delta^2 k}{(|{\mathbb F}|-1)^2}\right)^{1/8}\right)}. In particular, the blocklength of a linear 33-query LCC with constant distance over any small field grows exponentially with kk. This improves on the best prior lower bound of nΩ~(k3)n \geq \tilde{\Omega}(k^3) [AGKM23], which holds even for the weaker setting of 33-query locally decodable codes (LDCs), and comes close to matching the best-known construction of 33-query LCCs based on binary Reed-Muller codes, which achieve n2O(k1/2)n \leq 2^{O(k^{1/2})}. Because there is a 33-query LDC with a strictly subexponential blocklength [Yek08, Efr09], as a corollary we obtain the first strong separation between qq-query LCCs and LDCs for any constant q3q \geq 3. Our proof is based on a new upgrade of the method of spectral refutations via Kikuchi matrices developed in recent works [GKM22, HKM23, AGKM23] that reduces establishing (non-)existence of combinatorial objects to proving unsatisfiability of associated XOR instances. Our key conceptual idea is to apply this method with XOR instances obtained via long-chain derivations, a structured variant of low-width resolution for XOR formulas from proof complexity [Gri01, Sch08].

Keywords

Cite

@article{arxiv.2311.00558,
  title  = {An Exponential Lower Bound for Linear 3-Query Locally Correctable Codes},
  author = {Pravesh K. Kothari and Peter Manohar},
  journal= {arXiv preprint arXiv:2311.00558},
  year   = {2023}
}
R2 v1 2026-06-28T13:08:38.117Z