Samplable Anonymous Aggregation for Private Federated Data Analysis
Abstract
We revisit the problem of designing scalable protocols for private statistics and private federated learning when each device holds its private data. Locally differentially private algorithms require little trust but are (provably) limited in their utility. Centrally differentially private algorithms can allow significantly better utility but require a trusted curator. This gap has led to significant interest in the design and implementation of simple cryptographic primitives, that can allow central-like utility guarantees without having to trust a central server. Our first contribution is to propose a new primitive that allows for efficient implementation of several commonly used algorithms, and allows for privacy accounting that is close to that in the central setting without requiring the strong trust assumptions it entails. {\em Shuffling} and {\em aggregation} primitives that have been proposed in earlier works enable this for some algorithms, but have significant limitations as primitives. We propose a {\em Samplable Anonymous Aggregation} primitive, which computes an aggregate over a random subset of the inputs and show that it leads to better privacy-utility trade-offs for various fundamental tasks. Secondly, we propose a system architecture that implements this primitive and perform a security analysis of the proposed system. Our design combines additive secret-sharing with anonymization and authentication infrastructures.
Cite
@article{arxiv.2307.15017,
title = {Samplable Anonymous Aggregation for Private Federated Data Analysis},
author = {Kunal Talwar and Shan Wang and Audra McMillan and Vojta Jina and Vitaly Feldman and Pansy Bansal and Bailey Basile and Aine Cahill and Yi Sheng Chan and Mike Chatzidakis and Junye Chen and Oliver Chick and Mona Chitnis and Suman Ganta and Yusuf Goren and Filip Granqvist and Kristine Guo and Frederic Jacobs and Omid Javidbakht and Albert Liu and Richard Low and Dan Mascenik and Steve Myers and David Park and Wonhee Park and Gianni Parsa and Tommy Pauly and Christian Priebe and Rehan Rishi and Guy Rothblum and Michael Scaria and Linmao Song and Congzheng Song and Karl Tarbe and Sebastian Vogt and Luke Winstrom and Shundong Zhou},
journal= {arXiv preprint arXiv:2307.15017},
year = {2024}
}
Comments
34 pages