English

Preserving differential privacy under finite-precision semantics

Databases 2013-06-13 v1

Abstract

The approximation introduced by finite-precision representation of continuous data can induce arbitrarily large information leaks even when the computation using exact semantics is secure. Such leakage can thus undermine design efforts aimed at protecting sensitive information. We focus here on differential privacy, an approach to privacy that emerged from the area of statistical databases and is now widely applied also in other domains. In this approach, privacy is protected by the addition of noise to a true (private) value. To date, this approach to privacy has been proved correct only in the ideal case in which computations are made using an idealized, infinite-precision semantics. In this paper, we analyze the situation at the implementation level, where the semantics is necessarily finite-precision, i.e. the representation of real numbers and the operations on them, are rounded according to some level of precision. We show that in general there are violations of the differential privacy property, and we study the conditions under which we can still guarantee a limited (but, arguably, totally acceptable) variant of the property, under only a minor degradation of the privacy level. Finally, we illustrate our results on two cases of noise-generating distributions: the standard Laplacian mechanism commonly used in differential privacy, and a bivariate version of the Laplacian recently introduced in the setting of privacy-aware geolocation.

Keywords

Cite

@article{arxiv.1306.2691,
  title  = {Preserving differential privacy under finite-precision semantics},
  author = {Ivan Gazeau and Dale Miller and Catuscia Palamidessi},
  journal= {arXiv preprint arXiv:1306.2691},
  year   = {2013}
}

Comments

In Proceedings QAPL 2013, arXiv:1306.2413

R2 v1 2026-06-22T00:32:24.226Z