TY - GEN
T1 - Exploiting the Stochastic Gradient Descent Algorithm for Spatially Varying Deconvolution
AU - Rodriguez, Paul
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - Spatially varying degradation is related to real-world problems, such medical, astronomical, underwater or metalens imaging, neutron radiography, motion blur, optical remote sensing, etc. However, usually, spatially invariant blur is used as a proxy due to its relative computational simplicity w.r.t.The original problem. A spatially-variant PSF (point spread function) can be approxi-mated by a finite set of spatially weighted convolutions. While such structure limits a direct use of the (Fourier) Convolution theorem, the associated forward model can indeed be exploited by iterative optimizers, such ADMM or FISTA, or by model-Aware DL (deep learning) networks; these solutions still need large computational resources. In this paper we present a novel stochastic algorithm to solve the spatially varying deconvolution problem. Unlike other published stochastic deconvolution methods, which may be interpreted as a form of random walk, ours is based on manipulating the forward model to show that its gradient can be cast as a sum of independent functions, thus allowing a direct exploitation of the SGD (stochastic gradient descent). We also provide computational evidence (our code is publicly available) to support our theoretical analysis.
AB - Spatially varying degradation is related to real-world problems, such medical, astronomical, underwater or metalens imaging, neutron radiography, motion blur, optical remote sensing, etc. However, usually, spatially invariant blur is used as a proxy due to its relative computational simplicity w.r.t.The original problem. A spatially-variant PSF (point spread function) can be approxi-mated by a finite set of spatially weighted convolutions. While such structure limits a direct use of the (Fourier) Convolution theorem, the associated forward model can indeed be exploited by iterative optimizers, such ADMM or FISTA, or by model-Aware DL (deep learning) networks; these solutions still need large computational resources. In this paper we present a novel stochastic algorithm to solve the spatially varying deconvolution problem. Unlike other published stochastic deconvolution methods, which may be interpreted as a form of random walk, ours is based on manipulating the forward model to show that its gradient can be cast as a sum of independent functions, thus allowing a direct exploitation of the SGD (stochastic gradient descent). We also provide computational evidence (our code is publicly available) to support our theoretical analysis.
KW - SGD
KW - Spatially varying deconvolution
UR - https://www.scopus.com/pages/publications/105017773960
U2 - 10.1109/STSIVA66383.2025.11156507
DO - 10.1109/STSIVA66383.2025.11156507
M3 - Conference contribution
AN - SCOPUS:105017773960
T3 - 2025 25th Symposium of Image, Signal Processing, and Artificial Vision, STSIVA 2025
BT - 2025 25th Symposium of Image, Signal Processing, and Artificial Vision, STSIVA 2025
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 25th Symposium of Image, Signal Processing, and Artificial Vision, STSIVA 2025
Y2 - 27 August 2025 through 29 August 2025
ER -