Abstract
In phase retrieval, we want to recover an unknown signal $${{\varvec{x}}}\in {{\mathbb {C}}}^d$$ from n quadratic measurements of the form $$y_i = |\langle {{\varvec{a}}}_i,{{\varvec{x}}}\rangle |^2+w_i$$ , where $${{\varvec{a}}}_i\in {{\mathbb {C}}}^d$$ are known sensing vectors and $$w_i$$ is measurement noise. We ask the following weak recovery question: What is the minimum number of measurements n needed to produce an estimator $${\hat{{{\varvec{x}}}}}({{\varvec{y}}})$$ that is positively correlated with the signal $${{\varvec{x}}}$$ ? We consider the case of Gaussian vectors $${{\varvec{a}}}_i$$ . We prove that—in the high-dimensional limit—a sharp phase transition takes place, and we locate the threshold in the regime of vanishingly small noise. For $$n\le d-o(d)$$ , no estimator can do significantly better than random and achieve a strictly positive correlation. For $$n\ge d+o(d)$$ , a simple spectral estimator achieves a positive correlation. Surprisingly, numerical simulations with the same spectral estimator demonstrate promising performance with realistic sensing matrices. Spectral methods are used to initialize non-convex optimization algorithms in phase retrieval, and our approach can boost the performance in this setting as well. Our impossibility result is based on classical information-theoretic arguments. The spectral algorithm computes the leading eigenvector of a weighted empirical covariance matrix. We obtain a sharp characterization of the spectral properties of this random matrix using tools from free probability and generalizing a recent result by Lu and Li. Both the upper bound and lower bound generalize beyond phase retrieval to measurements $$y_i$$ produced according to a generalized linear model. As a by-product of our analysis, we compare the threshold of the proposed spectral method with that of a message passing algorithm.
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