Mutual Information Bounds in the Shuffle Model

Abstract

The shuffle model enhances privacy by anonymizing users' reports through random permutation. This paper presents the first systematic study of the single-message shuffle model from an information-theoretic perspective. We analyze two regimes: the shuffle-only setting, where each user directly submits its message (Yi=Xi), and the shuffle-DP setting, where each user first applies a local 0-differentially private mechanism before shuffling (Yi=R(Xi)). Let Z = (Yσ(i))i denote the shuffled sequence produced by a uniformly random permutation σ, and let K = σ-1(1) represent the position of user 1's message after shuffling. For the shuffle-only setting, we focus on a tractable yet expressive basic configuration, where the target user's message follows Y1 P and the remaining users' messages are i.i.d.\ samples from Q, i.e., Y2,…,Yn Q. We derive asymptotic expressions for the mutual information quantities I(Y1;Z) and I(K;Z) as n ∞, and demonstrate how this analytical framework naturally extends to settings with heterogeneous user distributions. For the shuffle-DP setting, we establish information-theoretic upper bounds on total information leakage. When each user applies an 0-DP mechanism, the overall leakage satisfies I(K; Z) 20 and I(X1; Z (Xi)i=2n) (e0-1)/(2n) + O(n-3/2). These results bridge shuffle differential privacy and mutual-information-based privacy.

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