Reconstruction and subgaussian operators

Abstract

We present a randomized method to approximate any vector v from some set T ⊂ n. The data one is given is the set T, and k scalar products (∈rXi,v)i=1k, where (Xi)i=1k are i.i.d. isotropic subgaussian random vectors in n, and k n. We show that with high probability, any y ∈ T for which (∈rXi,y)i=1k is close to the data vector (∈rXi,v)i=1k will be a good approximation of v, and that the degree of approximation is determined by a natural geometric parameter associated with the set T. We also investigate a random method to identify exactly any vector which has a relatively short support using linear subgaussian measurements as above. It turns out that our analysis, when applied to \-1,1\-valued vectors with i.i.d, symmetric entries, yields new information on the geometry of faces of random \-1,1\-polytope; we show that a k-dimensional random \-1,1\-polytope with n vertices is m-neighborly for very large m ck/ (c' n/k). The proofs are based on new estimates on the behavior of the empirical process f ∈ F |k-1Σi=1k f2(Xi) - f2 | when F is a subset of the L2 sphere. The estimates are given in terms of the γ2 functional with respect to the 2 metric on F, and hold both in exponential probability and in expectation.

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