On the Convex Geometry of Blind Deconvolution and Matrix Completion

Low‐rank matrix recovery from structured measurements has been a topic of intense study in the last decade and many important problems like matrix completion and blind deconvolution have been formulated in this framework. An important benchmark method to solve these problems is to minimize the nucle...

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Veröffentlicht in:	Communications on pure and applied mathematics 2021-04, Vol.74 (4), p.790-832
Hauptverfasser:	Krahmer, Felix, Stöger, Dominik
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Sprache:	eng
Schlagworte:	Applications of mathematics Conditioning Deconvolution Mathematical analysis Matrix methods Noise Noise levels Recovery
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description	Low‐rank matrix recovery from structured measurements has been a topic of intense study in the last decade and many important problems like matrix completion and blind deconvolution have been formulated in this framework. An important benchmark method to solve these problems is to minimize the nuclear norm, a convex proxy for the rank. A common approach to establish recovery guarantees for this convex program relies on the construction of a so‐called approximate dual certificate. However, this approach provides only limited insight into various respects. Most prominently, the noise bounds exhibit seemingly suboptimal dimension factors. In this paper we take a novel, more geometric viewpoint to analyze both the matrix completion and the blind deconvolution scenario. We find that for both these applications the dimension factors in the noise bounds are not an artifact of the proof, but the problems are intrinsically badly conditioned. We show, however, that bad conditioning only arises for very small noise levels: Under mild assumptions that include many realistic noise levels we derive near‐optimal error estimates for blind deconvolution under adversarial noise. © 2020 The Authors. Communications on Pure and Applied Mathematics published by Wiley Periodicals LLC
doi_str_mv	10.1002/cpa.21957
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subjects	Applications of mathematics Conditioning Deconvolution Mathematical analysis Matrix methods Noise Noise levels Recovery
title	On the Convex Geometry of Blind Deconvolution and Matrix Completion
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