Brownian Noise Reduction: Maximizing Privacy Subject to Accuracy Constraints

TL;DR

This paper introduces the Brownian mechanism, a Gaussian noise reduction technique that allows practitioners to balance privacy and accuracy dynamically, improving utility while maintaining strong privacy guarantees.

Contribution

It generalizes the noise reduction approach to Gaussian noise, enabling adaptive privacy control and better empirical performance in statistical tasks.

Findings

Empirically outperforms existing privacy mechanisms on statistical tasks.

Provides customizable privacy control during data interaction.

Maintains strong privacy guarantees with improved utility.

Abstract

There is a disconnect between how researchers and practitioners handle privacy-utility tradeoffs. Researchers primarily operate from a privacy first perspective, setting strict privacy requirements and minimizing risk subject to these constraints. Practitioners often desire an accuracy first perspective, possibly satisfied with the greatest privacy they can get subject to obtaining sufficiently small error. Ligett et al. have introduced a "noise reduction" algorithm to address the latter perspective. The authors show that by adding correlated Laplace noise and progressively reducing it on demand, it is possible to produce a sequence of increasingly accurate estimates of a private parameter while only paying a privacy cost for the least noisy iterate released. In this work, we generalize noise reduction to the setting of Gaussian noise, introducing the Brownian mechanism. The Brownian mechanism works by first adding Gaussian noise of high variance corresponding to the final point of a simulated Brownian motion. Then, at the practitioner's discretion, noise is gradually decreased by tracing back along the Brownian path to an earlier time. Our mechanism is more naturally applicable to the common setting of bounded $\ell_2$-sensitivity, empirically outperforms existing work on common statistical tasks, and provides customizable control of privacy loss over the entire interaction with the practitioner. We complement our Brownian mechanism with ReducedAboveThreshold, a generalization of the classical AboveThreshold algorithm that provides adaptive privacy guarantees. Overall, our results demonstrate that one can meet utility constraints while still maintaining strong levels of privacy.