Differentially Private Generalized Linear Models Revisited

Abstract

We study the problem of (ε,δ)-differentially private learning of linear predictors with convex losses. We provide results for two subclasses of loss functions. The first case is when the loss is smooth and non-negative but not necessarily Lipschitz (such as the squared loss). For this case, we establish an upper bound on the excess population risk of O( w*n + \ w* 2(nε)2/3,d w*2nε\), where n is the number of samples, d is the dimension of the problem, and w* is the minimizer of the population risk. Apart from the dependence on w, our bound is essentially tight in all parameters. In particular, we show a lower bound of (1n + \ w*4/3(nε)2/3, d w*nε\). We also revisit the previously studied case of Lipschitz losses [SSTT20]. For this case, we close the gap in the existing work and show that the optimal rate is (up to log factors) ( w*n + \ w*nε,rank w*nε\), where rank is the rank of the design matrix. This improves over existing work in the high privacy regime. Finally, our algorithms involve a private model selection approach that we develop to enable attaining the stated rates without a-priori knowledge of w*.

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