Deterministic APSP, Orthogonal Vectors, and More: Quickly Derandomizing Razborov-Smolensky

Author(s)

Chan, Timothy M; Williams, R Ryan

Abstract

© 2020 ACM. We show how to solve all-pairs shortest paths on n nodes in deterministic n3>/2>ω (s log n) time, and how to count the pairs of orthogonal vectors among n 0-1 vectors in d = clog n dimensions in deterministic n2-1/O(log c) time. These running times essentially match the best known randomized algorithms of Williams [46] and Abboud, Williams, and Yu [8], respectively, and the ability to count was open even for randomized algorithms. By reductions, these two results yield faster deterministic algorithms for many other problems. Our techniques can also be used to deterministically count k-satisfiability (k-SAT) assignments on n variable formulas in 2n-n/O(k) time, roughly matching the best known running times for detecting satisfiability and resolving an open problem of Santhanam [24]. A key to our constructions is an efficient way to deterministically simulate certain probabilistic polynomials critical to the algorithms of prior work, carefully applying small-biased sets and modulus-amplifying polynomials.

Date issued

2021

URI

https://hdl.handle.net/1721.1/143937

Department

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science
Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory

Journal

ACM Transactions on Algorithms

Publisher

Association for Computing Machinery (ACM)

Citation

Chan, Timothy M and Williams, R Ryan. 2021. "Deterministic APSP, Orthogonal Vectors, and More: Quickly Derandomizing Razborov-Smolensky." ACM Transactions on Algorithms, 17 (1).

Version: Author's final manuscript