English

Differentially Private Topological Data Analysis

Machine Learning 2023-11-06 v2 Computational Geometry Cryptography and Security Machine Learning Algebraic Topology

Abstract

This paper is the first to attempt differentially private (DP) topological data analysis (TDA), producing near-optimal private persistence diagrams. We analyze the sensitivity of persistence diagrams in terms of the bottleneck distance, and we show that the commonly used \v{C}ech complex has sensitivity that does not decrease as the sample size nn increases. This makes it challenging for the persistence diagrams of \v{C}ech complexes to be privatized. As an alternative, we show that the persistence diagram obtained by the L1L^1-distance to measure (DTM) has sensitivity O(1/n)O(1/n). Based on the sensitivity analysis, we propose using the exponential mechanism whose utility function is defined in terms of the bottleneck distance of the L1L^1-DTM persistence diagrams. We also derive upper and lower bounds of the accuracy of our privacy mechanism; the obtained bounds indicate that the privacy error of our mechanism is near-optimal. We demonstrate the performance of our privatized persistence diagrams through simulations as well as on a real dataset tracking human movement.

Keywords

Cite

@article{arxiv.2305.03609,
  title  = {Differentially Private Topological Data Analysis},
  author = {Taegyu Kang and Sehwan Kim and Jinwon Sohn and Jordan Awan},
  journal= {arXiv preprint arXiv:2305.03609},
  year   = {2023}
}

Comments

23 pages before references and appendices, 42 pages total, 8 figures

R2 v1 2026-06-28T10:27:02.316Z