English

Assessing differentially private deep learning with Membership Inference

Cryptography and Security 2020-05-27 v4 Machine Learning

Abstract

Attacks that aim to identify the training data of public neural networks represent a severe threat to the privacy of individuals participating in the training data set. A possible protection is offered by anonymization of the training data or training function with differential privacy. However, data scientists can choose between local and central differential privacy and need to select meaningful privacy parameters ϵ\epsilon which is challenging for non-privacy experts. We empirically compare local and central differential privacy mechanisms under white- and black-box membership inference to evaluate their relative privacy-accuracy trade-offs. We experiment with several datasets and show that this trade-off is similar for both types of mechanisms. This suggests that local differential privacy is a sound alternative to central differential privacy for differentially private deep learning, since small ϵ\epsilon in central differential privacy and large ϵ\epsilon in local differential privacy result in similar membership inference attack risk.

Keywords

Cite

@article{arxiv.1912.11328,
  title  = {Assessing differentially private deep learning with Membership Inference},
  author = {Daniel Bernau and Philip-William Grassal and Jonas Robl and Florian Kerschbaum},
  journal= {arXiv preprint arXiv:1912.11328},
  year   = {2020}
}
R2 v1 2026-06-23T12:55:39.705Z