Breaking the $n^{1.5}$ Additive Error Barrier for Private and Efficient Graph Sparsification via Private Expander Decomposition

July 02, 2025 Β· Declared Dead Β· πŸ› International Conference on Machine Learning

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Authors Anders Aamand, Justin Y. Chen, Mina Dalirrooyfard, Slobodan Mitrović, Yuriy Nevmyvaka, Sandeep Silwal, Yinzhan Xu arXiv ID 2507.01873 Category cs.DS: Data Structures & Algorithms Citations 0 Venue International Conference on Machine Learning Last Checked 4 months ago
Abstract
We study differentially private algorithms for graph cut sparsification, a fundamental problem in algorithms, privacy, and machine learning. While significant progress has been made, the best-known private and efficient cut sparsifiers on $n$-node graphs approximate each cut within $\widetilde{O}(n^{1.5})$ additive error and $1+Ξ³$ multiplicative error for any $Ξ³> 0$ [Gupta, Roth, Ullman TCC'12]. In contrast, "inefficient" algorithms, i.e., those requiring exponential time, can achieve an $\widetilde{O}(n)$ additive error and $1+Ξ³$ multiplicative error [Eli{Γ‘}{Ε‘}, Kapralov, Kulkarni, Lee SODA'20]. In this work, we break the $n^{1.5}$ additive error barrier for private and efficient cut sparsification. We present an $(\varepsilon,Ξ΄)$-DP polynomial time algorithm that, given a non-negative weighted graph, outputs a private synthetic graph approximating all cuts with multiplicative error $1+Ξ³$ and additive error $n^{1.25 + o(1)}$ (ignoring dependencies on $\varepsilon, Ξ΄, Ξ³$). At the heart of our approach lies a private algorithm for expander decomposition, a popular and powerful technique in (non-private) graph algorithms.
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