Sample-Efficient Private Learning of Mixtures of Gaussians

Abstract

We study the problem of learning mixtures of Gaussians with approximate differential privacy. We prove that roughly kd2 + k1.5 d1.75 + k2 d samples suffice to learn a mixture of k arbitrary d-dimensional Gaussians up to low total variation distance, with differential privacy. Our work improves over the previous best result [AAL24b] (which required roughly k2 d4 samples) and is provably optimal when d is much larger than k2. Moreover, we give the first optimal bound for privately learning mixtures of k univariate (i.e., 1-dimensional) Gaussians. Importantly, we show that the sample complexity for privately learning mixtures of univariate Gaussians is linear in the number of components k, whereas the previous best sample complexity [AAL21] was quadratic in k. Our algorithms utilize various techniques, including the inverse sensitivity mechanism [AD20b, AD20a, HKMN23], sample compression for distributions [ABDH+20], and methods for bounding volumes of sumsets.

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