ADMM based Fourier phase retrieval with untrained generative prior.

Fourier phase retrieval (FPR) is an inverse problem that aims to recover a signal from its Fourier magnitude measurement. It is an ill-posed problem, especially when the number of measurements is limited. In this paper, we introduce an untrained generative network that learns image priors without training on a large dataset to alleviate the ill-posedness. Based on the alternating direction method of multipliers (ADMM), an algorithm called Net-ADM that utilizes the untrained generative network is proposed to solve the FPR problem. Firstly, the dimension of the variable is increased and the objective function is modified to facilitate calculation. Then, an untrained generative network is embedded in the iterative process of ADMM to project an estimated signal into the generative space that captures some image characteristics. We theoretically prove the existence of a solution to the established model and analyze the convergence of the algorithm. Furthermore, one projection of Net-ADM makes the objective function non-increasing, while the other can bring the estimation closer to the optimal solution (or at least maintain the same distance) under certain conditions. Numerical experiments show that the proposed algorithm achieves superior accuracy and robustness compared to prior works, especially when the number of measurements is limited. • Net-ADM is proposed to solve the Fourier phase retrieval problem. • Net-ADM combines the Alternating Direction method of Multipliers with an untrained generative Network. • The descent of the objective function and the convergence of the iterations are analyzed theoretically. • The accuracy and robustness are superior to prior works, especially when the sampling ratios are low. [ABSTRACT FROM AUTHOR]