Sparsifying Suprema of Gaussian Processes
Abstract
We give a dimension-independent sparsification result for suprema of centered Gaussian processes: Let T be any (possibly infinite) bounded set of vectors in Rn, and let \Xt := t · g \t∈ T be the canonical Gaussian process on T, where g N(0, In). We show that there is an O(1)-size subset S ⊂eq T and a set of real values \cs\s ∈ S such that the random variable s ∈ S \Xs + cs\ is an -approximator\,(in L1) of the random variable t ∈ T Xt. Notably, the size of the sparsifier S is completely independent of both |T| and the ambient dimension n. We give two applications of this sparsification theorem: - A "Junta Theorem" for Norms: We show that given any norm (x) on Rn, there is another norm (x) depending only on the projection of x onto O(1) directions, for which (g) is a multiplicative (1 )-approximation of (g) with probability 1- for g N(0,In). - Sparsification of Convex Sets: We show that any intersection of (possibly infinitely many) halfspaces in Rn that are at distance r from the origin is -close (under N(0,In)) to an intersection of only Or,(1) halfspaces. This yields new polynomial-time agnostic learning and tolerant property testing algorithms for intersections of halfspaces.
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