Sparse Signal Recovery From Quadratic Systems with Full-Rank Matrices

Abstract

In signal processing and data recovery, reconstructing a signal from quadratic measurements poses a significant challenge, particularly in high-dimensional settings where measurements m is far less than the signal dimension n (i.e., m n). This paper addresses this problem by exploiting signal sparsity. Using tools from algebraic geometry, we derive theoretical recovery guarantees for sparse quadratic systems, showing that m 2s (real case) and m 4s-2 (complex case) generic measurements suffice to uniquely recover all s-sparse signals. Under a Gaussian measurement model, we propose a novel two-stage Sparse Gauss-Newton (SGN) algorithm. The first stage employs a support-restricted spectral initialization, yielding an accurate initial estimate with m=O(s2n) measurements. The second stage refines this estimate via an iterative hard-thresholding Gauss-Newton method, achieving quadratic convergence to the true signal within finitely many iterations when m O(sn). Compared to existing second-order methods, our algorithm achieves near-optimal sampling complexity for the refinement stage without requiring resampling. Numerical experiments indicate that SGN significantly outperforms state-of-the-art algorithms in both accuracy and computational efficiency. In particular, (1) when sparsity level s is high, compared with existing algorithms, SGN can achieve the same success rate with fewer measurements. (2) SGN converges with only about 1/10 iterations of the best existing algorithm and reach lower relative error.