(Nearly) Optimal Private Linear Regression via Adaptive Clipping

Abstract

We study the problem of differentially private linear regression where each data point is sampled from a fixed sub-Gaussian style distribution. We propose and analyze a one-pass mini-batch stochastic gradient descent method (DP-AMBSSGD) where points in each iteration are sampled without replacement. Noise is added for DP but the noise standard deviation is estimated online. Compared to existing (ε, δ)-DP techniques which have sub-optimal error bounds, DP-AMBSSGD is able to provide nearly optimal error bounds in terms of key parameters like dimensionality d, number of points N, and the standard deviation σ of the noise in observations. For example, when the d-dimensional covariates are sampled i.i.d. from the normal distribution, then the excess error of DP-AMBSSGD due to privacy is σ2 dN(1+dε2 N), i.e., the error is meaningful when number of samples N= (d d) which is the standard operative regime for linear regression. In contrast, error bounds for existing efficient methods in this setting are: O(d3ε2 N2), even for σ=0. That is, for constant ε, the existing techniques require N=(dd) to provide a non-trivial result.

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