On the Lattice Smoothing Parameter Problem

Abstract

The smoothing parameter ηε(L) of a Euclidean lattice L, introduced by Micciancio and Regev (FOCS'04; SICOMP'07), is (informally) the smallest amount of Gaussian noise that "smooths out" the discrete structure of L (up to error ε). It plays a central role in the best known worst-case/average-case reductions for lattice problems, a wealth of lattice-based cryptographic constructions, and (implicitly) the tightest known transference theorems for fundamental lattice quantities. In this work we initiate a study of the complexity of approximating the smoothing parameter to within a factor γ, denoted γ- GapSPP. We show that (for ε = 1/ poly(n)): (2+o(1))- GapSPP ∈ AM, via a Gaussian analogue of the classic Goldreich-Goldwasser protocol (STOC'98); (1+o(1))- GapSPP ∈ coAM, via a careful application of the Goldwasser-Sipser (STOC'86) set size lower bound protocol to thin spherical shells; (2+o(1))- GapSPP ∈ SZK ⊂eq AM coAM (where SZK is the class of problems having statistical zero-knowledge proofs), by constructing a suitable instance-dependent commitment scheme (for a slightly worse o(1)-term); (1+o(1))- GapSPP can be solved in deterministic 2O(n) polylog(1/ε) time and 2O(n) space. As an application, we demonstrate a tighter worst-case to average-case reduction for basing cryptography on the worst-case hardness of the GapSPP problem, with O(n) smaller approximation factor than the GapSVP problem. Central to our results are two novel, and nearly tight, characterizations of the magnitude of discrete Gaussian sums.