Near-Optimal differentially private low-rank trace regression with guaranteed private initialization

Abstract

We study differentially private (DP) estimation of a rank-r matrix M ∈ Rd1× d2 under the trace regression model with Gaussian measurement matrices. Theoretically, the sensitivity of non-private spectral initialization is precisely characterized, and the differential-privacy-constrained minimax lower bound for estimating M under the Schatten-q norm is established. Methodologically, the paper introduces a computationally efficient algorithm for DP-initialization with a sample size of n ≥ O (r2 (d1 d2)). Under certain regularity conditions, the DP-initialization falls within a local ball surrounding M. We also propose a differentially private algorithm for estimating M based on Riemannian optimization (DP-RGrad), which achieves a near-optimal convergence rate with the DP-initialization and sample size of n ≥ O(r (d1 + d2)). Finally, the paper discusses the non-trivial gap between the minimax lower bound and the upper bound of low-rank matrix estimation under the trace regression model. It is shown that the estimator given by DP-RGrad attains the optimal convergence rate in a weaker notion of differential privacy. Our powerful technique for analyzing the sensitivity of initialization requires no eigengap condition between r non-zero singular values.