English

SoK: Privacy-Preserving Data Synthesis

Cryptography and Security 2023-08-08 v2 Databases Machine Learning

Abstract

As the prevalence of data analysis grows, safeguarding data privacy has become a paramount concern. Consequently, there has been an upsurge in the development of mechanisms aimed at privacy-preserving data analyses. However, these approaches are task-specific; designing algorithms for new tasks is a cumbersome process. As an alternative, one can create synthetic data that is (ideally) devoid of private information. This paper focuses on privacy-preserving data synthesis (PPDS) by providing a comprehensive overview, analysis, and discussion of the field. Specifically, we put forth a master recipe that unifies two prominent strands of research in PPDS: statistical methods and deep learning (DL)-based methods. Under the master recipe, we further dissect the statistical methods into choices of modeling and representation, and investigate the DL-based methods by different generative modeling principles. To consolidate our findings, we provide comprehensive reference tables, distill key takeaways, and identify open problems in the existing literature. In doing so, we aim to answer the following questions: What are the design principles behind different PPDS methods? How can we categorize these methods, and what are the advantages and disadvantages associated with each category? Can we provide guidelines for method selection in different real-world scenarios? We proceed to benchmark several prominent DL-based methods on the task of private image synthesis and conclude that DP-MERF is an all-purpose approach. Finally, upon systematizing the work over the past decade, we identify future directions and call for actions from researchers.

Keywords

Cite

@article{arxiv.2307.02106,
  title  = {SoK: Privacy-Preserving Data Synthesis},
  author = {Yuzheng Hu and Fan Wu and Qinbin Li and Yunhui Long and Gonzalo Munilla Garrido and Chang Ge and Bolin Ding and David Forsyth and Bo Li and Dawn Song},
  journal= {arXiv preprint arXiv:2307.02106},
  year   = {2023}
}

Comments

Accepted at IEEE S&P (Oakland) 2024

R2 v1 2026-06-28T11:22:27.207Z