English

Sample-Efficient Low Rank Phase Retrieval

Information Theory 2021-02-25 v3 math.IT

Abstract

This work studies the Low Rank Phase Retrieval (LRPR) problem: recover an n×qn \times q rank-rr matrix XX^* from yk=Akxky_k = |A_k^\top x^*_k|, k=1,2,...,qk=1, 2,..., q, when each yky_k is an m-length vector containing independent phaseless linear projections of xkx^*_k. The different matrices AkA_k are i.i.d. and each contains i.i.d. standard Gaussian entries. We obtain an improved guarantee for AltMinLowRaP, which is an Alternating Minimization solution to LRPR that was introduced and studied in our recent work. As long as the right singular vectors of XX^* satisfy the incoherence assumption, we can show that the AltMinLowRaP estimate converges geometrically to XX^* if the total number of measurements mqnr2(r+log(1/ϵ))mq \gtrsim nr^2 (r + \log(1/\epsilon)). In addition, we also need mmax(r,logq,logn)m \gtrsim max(r, \log q, \log n) because of the specific asymmetric nature of our problem. Compared to our recent work, we improve the sample complexity of the AltMin iterations by a factor of r2r^2, and that of the initialization by a factor of rr. We also extend our result to the noisy case; we prove stability to corruption by small additive noise.

Keywords

Cite

@article{arxiv.2006.06198,
  title  = {Sample-Efficient Low Rank Phase Retrieval},
  author = {Seyedehsara Nayer and Namrata Vaswani},
  journal= {arXiv preprint arXiv:2006.06198},
  year   = {2021}
}

Comments

Revised for IEEE Trans. Info. Th

R2 v1 2026-06-23T16:13:34.816Z