Preserving Injectivity under Subgaussian Mappings and Its Application to Compressed Sensing

Abstract

The field of compressed sensing has become a major tool in high-dimensional analysis, with the realization that vectors can be recovered from relatively very few linear measurements as long as the vectors lie in a low-dimensional structure, typically the vectors that are zero in most coordinates with respect to a basis. However, there are many applications where we instead want to recover vectors that are sparse with respect to a dictionary rather than a basis. That is, we assume the vectors are linear combinations of at most s columns of a d × n matrix D, where s is very small relative to n and the columns of D form a (typically overcomplete) spanning set. In this direction, we show that as a matrix D stays bounded away from zero in norm on a set S and a provided map comprised of i.i.d. subgaussian rows has number of measurements at least proportional to the square of w(DS), the Gaussian width of the related set DS, then with high probability the composition D also stays bounded away from zero. As a specific application, we obtain that the null space property of order s is preserved under such subgaussian maps with high probability. Consequently, we obtain stable recovery guarantees for dictionary-sparse signals via the 1-synthesis method with only O(s(n/s)) random measurements and a minimal condition on D, which complements the compressed sensing literature.