English

Leveraging Diversity and Sparsity in Blind Deconvolution

Information Theory 2017-12-18 v2 math.IT

Abstract

This paper considers recovering LL-dimensional vectors w\boldsymbol{w}, and x1,x2,,xN\boldsymbol{x}_1,\boldsymbol{x}_2, \ldots, \boldsymbol{x}_N from their circular convolutions yn=wxn, n=1,2,3,,N\boldsymbol{y}_n = \boldsymbol{w}*\boldsymbol{x}_n, \ n = 1,2,3, \ldots, N. The vector w\boldsymbol{w} is assumed to be SS-sparse in a known basis that is spread out in the Fourier domain, and each input xn\boldsymbol{x}_n is a member of a known KK-dimensional random subspace. We prove that whenever K+Slog2SL/log4(LN)K + S\log^2S \lesssim L /\log^4(LN), the problem can be solved effectively by using only the nuclear-norm minimization as the convex relaxation, as long as the inputs are sufficiently diverse and obey Nlog2(LN)N \gtrsim \log^2(LN). By "diverse inputs", we mean that the xn\boldsymbol{x}_n's belong to different, generic subspaces. To our knowledge, this is the first theoretical result on blind deconvolution where the subspace to which w\boldsymbol{w} belongs is not fixed, but needs to be determined. We discuss the result in the context of multipath channel estimation in wireless communications. Both the fading coefficients, and the delays in the channel impulse response w\boldsymbol{w} are unknown. The encoder codes the KK-dimensional message vectors randomly and then transmits coded messages xn\boldsymbol{x}_n's over a fixed channel one after the other. The decoder then discovers all of the messages and the channel response when the number of samples taken for each received message are roughly greater than (K+Slog2S)log4(LN)(K+S\log^2S)\log^4(LN), and the number of messages is roughly at least log2(LN)\log^2(LN).

Cite

@article{arxiv.1610.06098,
  title  = {Leveraging Diversity and Sparsity in Blind Deconvolution},
  author = {Ali Ahmed and Laurent Demanet},
  journal= {arXiv preprint arXiv:1610.06098},
  year   = {2017}
}
R2 v1 2026-06-22T16:25:36.317Z