English

Using higher-order Fourier analysis over general fields

Data Structures and Algorithms 2015-05-05 v1 Computational Complexity Information Theory Combinatorics math.IT

Abstract

Higher-order Fourier analysis, developed over prime fields, has been recently used in different areas of computer science, including list decoding, algorithmic decomposition and testing. We extend the tools of higher-order Fourier analysis to analyze functions over general fields. Using these new tools, we revisit the results in the above areas. * For any fixed finite field K\mathbb{K}, we show that the list decoding radius of the generalized Reed Muller code over K\mathbb{K} equals the minimum distance of the code. Previously, this had been proved over prime fields [BL14] and for the case when K1|\mathbb{K}|-1 divides the order of the code [GKZ08]. * For any fixed finite field K\mathbb{K}, we give a polynomial time algorithm to decide whether a given polynomial P:KnKP: \mathbb{K}^n \to \mathbb{K} can be decomposed as a particular composition of lesser degree polynomials. This had been previously established over prime fields [Bha14, BHT15]. * For any fixed finite field K\mathbb{K}, we prove that all locally characterized affine-invariant properties of functions f:KnKf: \mathbb{K}^n \to \mathbb{K} are testable with one-sided error. The same result was known when K\mathbb{K} is prime [BFHHL13] and when the property is linear [KS08]. Moreover, we show that for any fixed finite field F\mathbb{F}, an affine-invariant property of functions f:KnFf: \mathbb{K}^n \to \mathbb{F}, where K\mathbb{K} is a growing field extension over F\mathbb{F}, is testable if it is locally characterized by constraints of bounded weight.

Keywords

Cite

@article{arxiv.1505.00619,
  title  = {Using higher-order Fourier analysis over general fields},
  author = {Arnab Bhattacharyya and Abhishek Bhowmick},
  journal= {arXiv preprint arXiv:1505.00619},
  year   = {2015}
}
R2 v1 2026-06-22T09:27:37.216Z