Sum-of-squares lower bounds for Non-Gaussian Component Analysis

Abstract

Non-Gaussian Component Analysis (NGCA) is the statistical task of finding a non-Gaussian direction in a high-dimensional dataset. Specifically, given i.i.d.\ samples from a distribution PAv on Rn that behaves like a known distribution A in a hidden direction v and like a standard Gaussian in the orthogonal complement, the goal is to approximate the hidden direction. The standard formulation posits that the first k-1 moments of A match those of the standard Gaussian and the k-th moment differs. Under mild assumptions, this problem has sample complexity O(n). On the other hand, all known efficient algorithms require (nk/2) samples. Prior work developed sharp Statistical Query and low-degree testing lower bounds suggesting an information-computation tradeoff for this problem. Here we study the complexity of NGCA in the Sum-of-Squares (SoS) framework. Our main contribution is the first super-constant degree SoS lower bound for NGCA. Specifically, we show that if the non-Gaussian distribution A matches the first (k-1) moments of N(0, 1) and satisfies other mild conditions, then with fewer than n(1 - )k/2 many samples from the normal distribution, with high probability, degree ( n)1 2-on(1) SoS fails to refute the existence of such a direction v. Our result significantly strengthens prior work by establishing a super-polynomial information-computation tradeoff against a broader family of algorithms. As corollaries, we obtain SoS lower bounds for several problems in robust statistics and the learning of mixture models. Our SoS lower bound proof introduces a novel technique, that we believe may be of broader interest, and a number of refinements over existing methods.

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