Beyond Ordinary Lipschitz Constraints: Differentially Private Stochastic Optimization with Tsybakov Noise Condition

Abstract

We study Stochastic Convex Optimization in the Differential Privacy model (DP-SCO). Unlike previous studies, here we assume the population risk function satisfies the Tsybakov Noise Condition (TNC) with some parameter θ>1, where the Lipschitz constant of the loss could be extremely large or even unbounded, but the 2-norm gradient of the loss has bounded k-th moment with k≥ 2. For the Lipschitz case with θ≥ 2, we first propose an (, δ)-DP algorithm whose utility bound is O((r2k(1n+(dn))k-1k)θθ-1) in high probability, where n is the sample size, d is the model dimension, and r2k is a term that only depends on the 2k-th moment of the gradient. It is notable that such an upper bound is independent of the Lipschitz constant. We then extend to the case where θ≥ θ> 1 for some known constant θ. Moreover, when the privacy budget is small enough, we show an upper bound of O((rk(1n+(dn))k-1k)θθ-1) even if the loss function is not Lipschitz. For the lower bound, we show that for any θ≥ 2, the private minimax rate for -zero Concentrated Differential Privacy is lower bounded by ((rk(1n+(dn))k-1k)θθ-1).