[论文解读] Scalable Incremental Nonconvex Optimization Approach for Phase Retrieval from Minimal Measurements

We aim to find a solution $\bm{x}\in\mathbb{R}^n/\mathbb{C}^n$ to a system of quadratic equations of the form $b_i=\lvert\langle\bm{a}_i,\bm{x} angle vert^2$, $i=1,2,\ldots,m$, e.g., the well-known phase retrieval problem, which is generally NP-hard. It has been proved that the number $m = 2n-1$ of generic random measurement vectors $\bm{a}_i\in\mathbb{R}^n$ is sufficient and necessary for uniquely determining the $n$-length real vector $\bm{x}$ up to a global sign. The uniqueness theory, however, does not provide a construction or characterization of this unique solution. As opposed to the recent nonconvex state-of-the-art solvers, we revert to the convex relaxation semidefinite programming (SDP) approach and propose to indirectly minimize the convex objective by successive and incremental nonconvex optimization, termed as exttt{IncrePR}, to overcome the excessive computation cost of typical SDP solvers. exttt{IncrePR} avoids sensitive dependence of initialization of nonconvex approaches and achieves global convergence, which makes it also promising for more general models and measurements. For real Gaussian model, exttt{IncrePR} achieves perfect recovery from $m=2n-1$ noiseless measurement and the recovery is stable from noisy measurement. When applying exttt{IncrePR} for structured (non-Gaussian) measurements, such as transmission matrix and oversampling Fourier measurement, it can also locate a reconstruction close to true reconstruction with few measurements. Extensive numerical tests show that exttt{IncrePR} outperforms other state-of-the-art methods in the sharpest phase transition of perfect recovery for Gaussian model and the best reconstruction quality for other non-Gaussian models, in particular Fourier phase retrieval.