English

Smooth Sensitivity Revisited: Towards Optimality

Cryptography and Security 2024-07-09 v1

Abstract

Smooth sensitivity is one of the most commonly used techniques for designing practical differentially private mechanisms. In this approach, one computes the smooth sensitivity of a given query qq on the given input DD and releases q(D)q(D) with noise added proportional to this smooth sensitivity. One question remains: what distribution should we pick the noise from? In this paper, we give a new class of distributions suitable for the use with smooth sensitivity, which we name the PolyPlace distribution. This distribution improves upon the state-of-the-art Student's T distribution in terms of standard deviation by arbitrarily large factors, depending on a "smoothness parameter" γ\gamma, which one has to set in the smooth sensitivity framework. Moreover, our distribution is defined for a wider range of parameter γ\gamma, which can lead to significantly better performance. Moreover, we prove that the PolyPlace distribution converges for γ0\gamma \rightarrow 0 to the Laplace distribution and so does its variance. This means that the Laplace mechanism is a limit special case of the PolyPlace mechanism. This implies that out mechanism is in a certain sense optimal for γ0\gamma \to 0.

Keywords

Cite

@article{arxiv.2407.05067,
  title  = {Smooth Sensitivity Revisited: Towards Optimality},
  author = {Richard Hladík and Jakub Tětek},
  journal= {arXiv preprint arXiv:2407.05067},
  year   = {2024}
}
R2 v1 2026-06-28T17:31:16.911Z