Learning with Differentially Private (Sliced) Wasserstein Gradients
Abstract
In this work, we introduce a novel framework for privately optimizing objectives that rely on Wasserstein distances between data-dependent empirical measures. Our main theoretical contribution is, based on an explicit formulation of the Wasserstein gradient in a fully discrete setting, a control on the sensitivity of this gradient to individual data points, allowing strong privacy guarantees at minimal utility cost. Building on these insights, we develop a deep learning approach that incorporates gradient and activations clipping, originally designed for DP training of problems with a finite-sum structure. We further demonstrate that privacy accounting methods extend to Wasserstein-based objectives, facilitating large-scale private training. Empirical results confirm that our framework effectively balances accuracy and privacy, offering a theoretically sound solution for privacy-preserving machine learning tasks relying on optimal transport distances such as Wasserstein distance or sliced-Wasserstein distance.
Cite
@article{arxiv.2502.01701,
title = {Learning with Differentially Private (Sliced) Wasserstein Gradients},
author = {David Rodríguez-Vítores and Clément Lalanne and Jean-Michel Loubes},
journal= {arXiv preprint arXiv:2502.01701},
year = {2025}
}