Improved Robust Estimation for Erdos-R\'enyi Graphs: The Sparse Regime and Optimal Breakdown Point

Abstract

We study the problem of robustly estimating the edge density of Erdos-R\'enyi random graphs G(n, d/n) when an adversary can arbitrarily add or remove edges incident to an η-fraction of the nodes. We develop the first polynomial-time algorithm for this problem that estimates d up to an additive error O([(n) / n + η(1/η) ] · d + η (1/η)). Our error guarantee matches information-theoretic lower bounds up to factors of (1/η). Moreover, our estimator works for all d ≥ (1) and achieves optimal breakdown point η = 1/2. Previous algorithms [AJK+22, CDHS24], including inefficient ones, incur significantly suboptimal errors. Furthermore, even admitting suboptimal error guarantees, only inefficient algorithms achieve optimal breakdown point. Our algorithm is based on the sum-of-squares (SoS) hierarchy. A key ingredient is to construct constant-degree SoS certificates for concentration of the number of edges incident to small sets in G(n, d/n). Crucially, we show that these certificates also exist in the sparse regime, when d = o( n), a regime in which the performance of previous algorithms was significantly suboptimal.

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