(Gap/S)ETH Hardness of SVP

Abstract

[1]#1 SVP [1]#1 We prove the following quantitative hardness results for the Shortest Vector Problem in the p norm (p), where n is the rank of the input lattice. For "almost all" p > p0 ≈ 2.1397, there no 2n/Cp-time algorithm for p for some explicit constant Cp > 0 unless the (randomized) Strong Exponential Time Hypothesis (SETH) is false. For any p > 2, there is no 2o(n)-time algorithm for p unless the (randomized) Gap-Exponential Time Hypothesis (Gap-ETH) is false. Furthermore, for each p > 2, there exists a constant γp > 1 such that the same result holds even for γp-approximate p. There is no 2o(n)-time algorithm for p for any 1 ≤ p ≤ 2 unless either (1) (non-uniform) Gap-ETH is false; or (2) there is no family of lattices with exponential kissing number in the 2 norm. Furthermore, for each 1 ≤ p ≤ 2, there exists a constant γp > 1 such that the same result holds even for γp-approximate p.