Near Optimal Algorithms for Noisy k-XOR under Low-Degree Heuristic

Abstract

Noisy k-XOR is a basic average-case inference problem in which one observes random noisy k-ary parity constraints and seeks to recover, or more weakly, detect, a hidden Boolean assignment. A central question is to characterize the tradeoff among sample complexity, noise level, and running time. We give a recovery algorithm, and hence also a detection algorithm, for noisy k-XOR in the high-noise regime. For every parameter D, our algorithm runs in time nD+O(1) and succeeds whenever m Ck nk/2D\,k/2-1δ2, where Ck is an explicit constant depending only on k, and δ is the noise bias. Our result matches the best previously known time--sample tradeoff for detection, while simultaneously yielding recovery guarantees. In addition, the dependence on the noise bias δ is optimal up to constant factors, matching the information-theoretic scaling. We also prove matching low-degree lower bounds. In particular, we show that the degree-D low-degree likelihood ratio has bounded L2-norm below the same threshold, up to the same factor Dk/2-1. Under the low-degree heuristic, this implies that our algorithm is near-optimal over a broad range of parameters. Our approach combines a refined second-moment analysis with color coding and dynamic programming for structured hypergraph embedding statistics. These techniques may be of independent interest for other average-case inference problems.