Instance optimality in phase retrieval

Abstract

Compressed sensing has demonstrated that a general signal x ∈ Fn (F∈ \R,C\) can be estimated from few linear measurements with an error proportional to the best k-term approximation error, a property known as instance optimality. In this paper, we investigate instance optimality in the context of phaseless measurements using the p-minimization decoder, where p ∈ (0, 1], for both real and complex cases. More specifically, we prove that (2,1) and (1,1)-instance optimality of order k can be achieved with m =O(k (n/k)) phaseless measurements, paralleling results from linear measurements. These results imply that one can stably recover approximately k-sparse signals from m = O(k (n/k)) phaseless measurements. Our approach leverages the phaseless bi-Lipschitz condition. Additionally, we present a non-uniform version of (2,2)-instance optimality result in probability applicable to any fixed vector x ∈ Fn. These findings reveal striking parallels between compressive phase retrieval and classical compressed sensing, enhancing our understanding of both phase retrieval and instance optimality.

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