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Convex and Nonconvex Optimization Are Both Minimax-Optimal for Noisy Blind Deconvolution Under Random Designs

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Version 2 2023-05-30, 19:44
Version 1 2021-07-21, 18:40
journal contribution
posted on 2023-05-30, 19:44 authored by Yuxin Chen, Jianqing Fan, Bingyan Wang, Yuling Yan

We investigate the effectiveness of convex relaxation and nonconvex optimization in solving bilinear systems of equations under two different designs (i.e., a sort of random Fourier design and Gaussian design). Despite the wide applicability, the theoretical understanding about these two paradigms remains largely inadequate in the presence of random noise. The current article makes two contributions by demonstrating that (i) a two-stage nonconvex algorithm attains minimax-optimal accuracy within a logarithmic number of iterations, and (ii) convex relaxation also achieves minimax-optimal statistical accuracy vis-à-vis random noise. Both results significantly improve upon the state-of-the-art theoretical guarantees. Supplementary materials for this article are available online.

Funding

Y. Chen is supported in part by the AFOSR YIP award FA9550-19-1-0030, by the ONR grant N00014-19-1-2120, by the ARO grants W911NF-20-1-0097 and W911NF-18-1-0303, by the NSF grants CCF-1907661, IIS-1900140, IIS-2100158 and DMS-2014279, and by the Princeton SEAS innovation award. J. Fan is supported in part by the ONR grant N00014-19-1-2120 and the NSF grants DMS-1662139, DMS-1712591, DMS-2052926, DMS-2053832, and the NIH grant 2R01-GM072611-15. B. Wang is supported in part by the Gordon Y. S. Wu Fellowship in Engineering.

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    Journal of the American Statistical Association

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    Keywords

    Blind deconvolutionBilinear systems of equationsConvex relaxationNonconvex optimizationLeave-one-out analysis

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    CC BY 4.0

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