Better and Simpler Lower Bounds for Differentially Private Statistical Estimation

Abstract

We provide optimal lower bounds for two well-known parameter estimation (also known as statistical estimation) tasks in high dimensions with approximate differential privacy. First, we prove that for any α O(1), estimating the covariance of a Gaussian up to spectral error α requires (d3/2α + dα2) samples, which is tight up to logarithmic factors. This result improves over previous work which established this for α O(1d), and is also simpler than previous work. Next, we prove that estimating the mean of a heavy-tailed distribution with bounded kth moments requires (dαk/(k-1) + dα2) samples. Previous work for this problem was only able to establish this lower bound against pure differential privacy, or in the special case of k = 2. Our techniques follow the method of fingerprinting and are generally quite simple. Our lower bound for heavy-tailed estimation is based on a black-box reduction from privately estimating identity-covariance Gaussians. Our lower bound for covariance estimation utilizes a Bayesian approach to show that, under an Inverse Wishart prior distribution for the covariance matrix, no private estimator can be accurate even in expectation, without sufficiently many samples.

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