English

Probabilistic Polynomials and Hamming Nearest Neighbors

Data Structures and Algorithms 2016-11-18 v1 Computational Complexity Combinatorics

Abstract

We show how to compute any symmetric Boolean function on nn variables over any field (as well as the integers) with a probabilistic polynomial of degree O(nlog(1/ϵ))O(\sqrt{n \log(1/\epsilon)}) and error at most ϵ\epsilon. The degree dependence on nn and ϵ\epsilon is optimal, matching a lower bound of Razborov (1987) and Smolensky (1987) for the MAJORITY function. The proof is constructive: a low-degree polynomial can be efficiently sampled from the distribution. This polynomial construction is combined with other algebraic ideas to give the first subquadratic time algorithm for computing a (worst-case) batch of Hamming distances in superlogarithmic dimensions, exactly. To illustrate, let c(n):NNc(n) : \mathbb{N} \rightarrow \mathbb{N}. Suppose we are given a database DD of nn vectors in {0,1}c(n)logn\{0,1\}^{c(n) \log n} and a collection of nn query vectors QQ in the same dimension. For all uQu \in Q, we wish to compute a vDv \in D with minimum Hamming distance from uu. We solve this problem in n21/O(c(n)log2c(n))n^{2-1/O(c(n) \log^2 c(n))} randomized time. Hence, the problem is in "truly subquadratic" time for O(logn)O(\log n) dimensions, and in subquadratic time for d=o((log2n)/(loglogn)2)d = o((\log^2 n)/(\log \log n)^2). We apply the algorithm to computing pairs with maximum inner product, closest pair in 1\ell_1 for vectors with bounded integer entries, and pairs with maximum Jaccard coefficients.

Keywords

Cite

@article{arxiv.1507.05106,
  title  = {Probabilistic Polynomials and Hamming Nearest Neighbors},
  author = {Josh Alman and Ryan Williams},
  journal= {arXiv preprint arXiv:1507.05106},
  year   = {2016}
}

Comments

16 pages. To appear in 56th Annual IEEE Symposium on Foundations of Computer Science (FOCS 2015)

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