Error Bound of Empirical 2 Risk Minimization for Noisy Standard and Generalized Phase Retrieval Problems
Abstract
In this paper, we study the estimation performance of empirical 2 risk minimization (ERM) in noisy (standard) phase retrieval (NPR) given by yk = |αk*x0|2+ηk, or noisy generalized phase retrieval (NGPR) formulated as yk = x0*Akx0 + ηk, where x0∈Kd is the desired signal, n is the sample size, η= (η1,...,ηn) is the noise vector. We establish new error bounds under different noise patterns, and our proofs are valid for both K=R and K=C. In NPR under arbitrary noise vector η, we derive a new error bound O(\|η\|∞dn + |1η|n), which is tighter than the currently known one O(\|η\|n) in many cases. In NGPR, we show O(\|η\|dn) for arbitrary η. In both problems, the bounds for arbitrary noise immediately give rise to O(dn) for sub-Gaussian or sub-exponential random noise, with some conventional but inessential assumptions (e.g., independent or zero-mean condition) removed or weakened. In addition, we make a first attempt to ERM under heavy-tailed random noise assumed to have bounded l-th moment. To achieve a trade-off between bias and variance, we truncate the responses and propose a corresponding robust ERM estimator, which is shown to possess the guarantee O([dn]1-1/l) in both NPR, NGPR. All the error bounds straightforwardly extend to the more general problems of rank-r matrix recovery, and these results deliver a conclusion that the full-rank frame \Ak\k=1n in NGPR is more robust to biased noise than the rank-1 frame \αkαk*\k=1n in NPR. Extensive experimental results are presented to illustrate our theoretical findings.
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