English

Bilinear Recovery using Adaptive Vector-AMP

Information Theory 2019-06-26 v2 math.IT

Abstract

We consider the problem of jointly recovering the vector b\boldsymbol{b} and the matrix C\boldsymbol{C} from noisy measurements Y=A(b)C+W\boldsymbol{Y} = \boldsymbol{A}(\boldsymbol{b})\boldsymbol{C} + \boldsymbol{W}, where A()\boldsymbol{A}(\cdot) is a known affine linear function of b\boldsymbol{b} (i.e., A(b)=A0+i=1QbiAi\boldsymbol{A}(\boldsymbol{b})=\boldsymbol{A}_0+\sum_{i=1}^Q b_i \boldsymbol{A}_i with known matrices Ai\boldsymbol{A}_i). This problem has applications in matrix completion, robust PCA, dictionary learning, self-calibration, blind deconvolution, joint-channel/symbol estimation, compressive sensing with matrix uncertainty, and many other tasks. To solve this bilinear recovery problem, we propose the Bilinear Adaptive Vector Approximate Message Passing (BAd-VAMP) algorithm. We demonstrate numerically that the proposed approach is competitive with other state-of-the-art approaches to bilinear recovery, including lifted VAMP and Bilinear GAMP.

Keywords

Cite

@article{arxiv.1809.00024,
  title  = {Bilinear Recovery using Adaptive Vector-AMP},
  author = {Subrata Sarkar and Alyson K. Fletcher and Sundeep Rangan and Philip Schniter},
  journal= {arXiv preprint arXiv:1809.00024},
  year   = {2019}
}
R2 v1 2026-06-23T03:51:04.810Z