Optimal spectral initializers impact on phase retrieval phase transitions -- an RDT view

Abstract

We analyze the relation between spectral initializers and theoretical limits of descending phase retrieval algorithms (dPR). In companion paper [104], for any sample complexity ratio, α, parametric manifold, PM(α), is recognized as a critically important structure that generically determines dPRs abilities to solve phase retrieval (PR). Moreover, overlap between the algorithmic solution and the true signal is positioned as a key PM's component. We here consider the so-called overlap optimal spectral initializers (OptSpins) as dPR's starting points and develop a generic Random duality theory (RDT) based program to statistically characterize them. In particular, we determine the functional structure of OptSpins and evaluate the starting overlaps that they provide for the dPRs. Since PM's so-called flat regions are highly susceptible to local jitteriness and as such are key obstacles on dPR's path towards PR's global optimum, a precise characterization of the starting overlap allows to determine if such regions can be successfully circumvented. Through the presented theoretical analysis we observe two key points in that regard: (i) dPR's theoretical phase transition (critical α above which they solve PR) might be difficult to practically achieve as the PM's flat regions are large causing the associated OptSpins to fall exactly within them; and (ii) Opting for so-called ``safer compression'' and slightly increasing α (by say 15\%) shrinks flat regions and allows OptSpins to fall outside them and dPRs to ultimately solve PR. Numerical simulations are conducted as well and shown to be in an excellent agreement with theoretical predictions.