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Main Authors: Brown, Gavin, Gaboardi, Marco, Smith, Adam, Ullman, Jonathan, Zakynthinou, Lydia
Format: Preprint
Published: 2021
Subjects:
Online Access:https://arxiv.org/abs/2106.13329
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author Brown, Gavin
Gaboardi, Marco
Smith, Adam
Ullman, Jonathan
Zakynthinou, Lydia
author_facet Brown, Gavin
Gaboardi, Marco
Smith, Adam
Ullman, Jonathan
Zakynthinou, Lydia
contents We present two sample-efficient differentially private mean estimators for $d$-dimensional (sub)Gaussian distributions with unknown covariance. Informally, given $n \gtrsim d/α^2$ samples from such a distribution with mean $μ$ and covariance $Σ$, our estimators output $\tildeμ$ such that $\| \tildeμ- μ\|_Σ \leq α$, where $\| \cdot \|_Σ$ is the Mahalanobis distance. All previous estimators with the same guarantee either require strong a priori bounds on the covariance matrix or require $Ω(d^{3/2})$ samples. Each of our estimators is based on a simple, general approach to designing differentially private mechanisms, but with novel technical steps to make the estimator private and sample-efficient. Our first estimator samples a point with approximately maximum Tukey depth using the exponential mechanism, but restricted to the set of points of large Tukey depth. Its accuracy guarantees hold even for data sets that have a small amount of adversarial corruption. Proving that this mechanism is private requires a novel analysis. Our second estimator perturbs the empirical mean of the data set with noise calibrated to the empirical covariance, without releasing the covariance itself. Its sample complexity guarantees hold more generally for subgaussian distributions, albeit with a slightly worse dependence on the privacy parameter. For both estimators, careful preprocessing of the data is required to satisfy differential privacy.
format Preprint
id arxiv_https___arxiv_org_abs_2106_13329
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publishDate 2021
record_format arxiv
spellingShingle Covariance-Aware Private Mean Estimation Without Private Covariance Estimation
Brown, Gavin
Gaboardi, Marco
Smith, Adam
Ullman, Jonathan
Zakynthinou, Lydia
Machine Learning
We present two sample-efficient differentially private mean estimators for $d$-dimensional (sub)Gaussian distributions with unknown covariance. Informally, given $n \gtrsim d/α^2$ samples from such a distribution with mean $μ$ and covariance $Σ$, our estimators output $\tildeμ$ such that $\| \tildeμ- μ\|_Σ \leq α$, where $\| \cdot \|_Σ$ is the Mahalanobis distance. All previous estimators with the same guarantee either require strong a priori bounds on the covariance matrix or require $Ω(d^{3/2})$ samples. Each of our estimators is based on a simple, general approach to designing differentially private mechanisms, but with novel technical steps to make the estimator private and sample-efficient. Our first estimator samples a point with approximately maximum Tukey depth using the exponential mechanism, but restricted to the set of points of large Tukey depth. Its accuracy guarantees hold even for data sets that have a small amount of adversarial corruption. Proving that this mechanism is private requires a novel analysis. Our second estimator perturbs the empirical mean of the data set with noise calibrated to the empirical covariance, without releasing the covariance itself. Its sample complexity guarantees hold more generally for subgaussian distributions, albeit with a slightly worse dependence on the privacy parameter. For both estimators, careful preprocessing of the data is required to satisfy differential privacy.
title Covariance-Aware Private Mean Estimation Without Private Covariance Estimation
topic Machine Learning
url https://arxiv.org/abs/2106.13329