Time-Aware Projections: Node-Private Graph Statistics

The author introduces time-aware projection algorithms for node-private graph statistics, ensuring stability and privacy in continual release settings.

The content discusses the challenges of releasing private statistics about social network data and presents novel algorithms that ensure node-differential privacy in a continual release setting. The stability of the projection algorithms is analyzed, providing insights into their performance on varying graph streams. Releasing differentially private statistics about social network data is challenging due to sensitivity to unusual nodes. New algorithms ensure node-differential privacy without assumptions on input streams, offering accurate results for fundamental graph problems. Previous works exhibit privacy violations when degree bounds are not met, prompting the development of unconditionally private algorithms with optimal error rates. Novel projection algorithms for graph streams limit degrees to ensure stability and privacy, enabling accurate estimates for various graph statistics. The transformation from restricted-DP to truly private algorithms ensures accuracy while maintaining privacy guarantees across different types of graphs.

For every graph G with n vertices, there is a node-neighboring graph G′ with n more edges. A node-private algorithm must hide the difference between two graphs with additive error Ω(n). The projections are stable when the input stream satisfies a privately testable safety condition.

"Differential privacy is a widely studied and deployed framework for quantifying such a trade-off." - [DMNS16] "In this work, we study differentially private algorithms that continually monitor several fundamental statistics about a graph that evolves over time." - Content