ASYNC-RED: A PROVABLY CONVERGENT ASYNCHRONOUS BLOCK PARALLEL STOCHASTIC METHOD USING DEEP DENOISING PRIORS

Yu Sun; Jiaming Liu; Yiran Sun; Brendt Wohlberg; Ulugbek S. Kamilov

ASYNC-RED: A PROVABLY CONVERGENT ASYNCHRONOUS BLOCK PARALLEL STOCHASTIC METHOD USING DEEP DENOISING PRIORS

Yu Sun, Jiaming Liu, Yiran Sun, Brendt Wohlberg, Ulugbek S. Kamilov

Research output: Contribution to conference › Paper › peer-review

Abstract

Regularization by denoising (RED) is a recently developed framework for solving inverse problems by integrating advanced denoisers as image priors. Recent work has shown its state-of-the-art performance when combined with pre-trained deep denoisers. However, current RED algorithms are inadequate for parallel processing on multicore systems. We address this issue by proposing a new asynchronous RED (ASYNC-RED) algorithm that enables asynchronous parallel processing of data, making it significantly faster than its serial counterparts for large-scale inverse problems. The computational complexity of ASYNC-RED is further reduced by using a random subset of measurements at every iteration. We present complete theoretical analysis of the algorithm by establishing its convergence under explicit assumptions on the data-fidelity and the denoiser. We validate ASYNC-RED on image recovery using pre-trained deep denoisers as priors.

Original language	English
State	Published - 2021
Event	9th International Conference on Learning Representations, ICLR 2021 - Virtual, Online Duration: May 3 2021 → May 7 2021

Conference

Conference	9th International Conference on Learning Representations, ICLR 2021
City	Virtual, Online
Period	05/3/21 → 05/7/21

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@conference{7688a49d4b2247be8207c9173e3e262f,

title = "ASYNC-RED: A PROVABLY CONVERGENT ASYNCHRONOUS BLOCK PARALLEL STOCHASTIC METHOD USING DEEP DENOISING PRIORS",

abstract = "Regularization by denoising (RED) is a recently developed framework for solving inverse problems by integrating advanced denoisers as image priors. Recent work has shown its state-of-the-art performance when combined with pre-trained deep denoisers. However, current RED algorithms are inadequate for parallel processing on multicore systems. We address this issue by proposing a new asynchronous RED (ASYNC-RED) algorithm that enables asynchronous parallel processing of data, making it significantly faster than its serial counterparts for large-scale inverse problems. The computational complexity of ASYNC-RED is further reduced by using a random subset of measurements at every iteration. We present complete theoretical analysis of the algorithm by establishing its convergence under explicit assumptions on the data-fidelity and the denoiser. We validate ASYNC-RED on image recovery using pre-trained deep denoisers as priors.",

author = "Yu Sun and Jiaming Liu and Yiran Sun and Brendt Wohlberg and Kamilov, {Ulugbek S.}",

note = "Publisher Copyright: {\textcopyright} 2021 ICLR 2021 - 9th International Conference on Learning Representations. All rights reserved.; 9th International Conference on Learning Representations, ICLR 2021 ; Conference date: 03-05-2021 Through 07-05-2021",

year = "2021",

language = "English",

}

TY - CONF

T1 - ASYNC-RED

T2 - 9th International Conference on Learning Representations, ICLR 2021

AU - Sun, Yu

AU - Liu, Jiaming

AU - Sun, Yiran

AU - Wohlberg, Brendt

AU - Kamilov, Ulugbek S.

PY - 2021

Y1 - 2021

N2 - Regularization by denoising (RED) is a recently developed framework for solving inverse problems by integrating advanced denoisers as image priors. Recent work has shown its state-of-the-art performance when combined with pre-trained deep denoisers. However, current RED algorithms are inadequate for parallel processing on multicore systems. We address this issue by proposing a new asynchronous RED (ASYNC-RED) algorithm that enables asynchronous parallel processing of data, making it significantly faster than its serial counterparts for large-scale inverse problems. The computational complexity of ASYNC-RED is further reduced by using a random subset of measurements at every iteration. We present complete theoretical analysis of the algorithm by establishing its convergence under explicit assumptions on the data-fidelity and the denoiser. We validate ASYNC-RED on image recovery using pre-trained deep denoisers as priors.

AB - Regularization by denoising (RED) is a recently developed framework for solving inverse problems by integrating advanced denoisers as image priors. Recent work has shown its state-of-the-art performance when combined with pre-trained deep denoisers. However, current RED algorithms are inadequate for parallel processing on multicore systems. We address this issue by proposing a new asynchronous RED (ASYNC-RED) algorithm that enables asynchronous parallel processing of data, making it significantly faster than its serial counterparts for large-scale inverse problems. The computational complexity of ASYNC-RED is further reduced by using a random subset of measurements at every iteration. We present complete theoretical analysis of the algorithm by establishing its convergence under explicit assumptions on the data-fidelity and the denoiser. We validate ASYNC-RED on image recovery using pre-trained deep denoisers as priors.

UR - http://www.scopus.com/inward/record.url?scp=85101949699&partnerID=8YFLogxK

M3 - Paper

AN - SCOPUS:85101949699

Y2 - 3 May 2021 through 7 May 2021

ER -

ASYNC-RED: A PROVABLY CONVERGENT ASYNCHRONOUS BLOCK PARALLEL STOCHASTIC METHOD USING DEEP DENOISING PRIORS

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