Your search keyword '"Variational inference framework"' showing total 2 results

1. Image restoration for optical synthetic aperture system via variational physics-informed network

Author

Bu Ning, Mei Hui, Ming Liu, Liquan Dong, Lingqin Kong, and Yuejin Zhao

Subjects

Optical synthetic aperture, Variational inference framework, VPIN, Physics, QC1-999

Abstract

Optical synthetic aperture with homogeneous circular sub-mirrors greatly improves the spatial resolution of space telescopes; however, the discrete and sparse characteristics of the sub-mirrors reduce the mid-frequency modulation transfer function (MTF), resulting in blurred images being obtained. In this paper, a method combining variational physics-informed with deep learning is presented, which shows blind image restoration without complex priors. The constraint effect of traditional maximum a posterior (MAP) framework is removed by variational inference framework, which is embedded into Variational Physics-informed Network (VPIN) to optimize neural network training. Residual dense blocks (RDBs) construction is contributed to image feature extraction. Networks with SSIM-corrected loss functions can be trained at the feature level to help with convergence. When SNR = 30 dB, the PSNR of Golay-6 remote sensing test set increases from 20.16 dB to 23.90 dB, SSIM is from 0.610 to 0.842, and MS-SSIM is from 0.930 to 0.955.

Published

2023

2. Image restoration for optical synthetic aperture system via variational physics-informed network.

Author

Ning, Bu, Hui, Mei, Liu, Ming, Dong, Liquan, Kong, Lingqin, and Zhao, Yuejin

Abstract

• The constraint effect of maximum a posterior (MAP) framework is removed by variational inference framework. • Variational inference framework is embedded and Variational Physics-informed Network is designed and developed. • Blind restoration is presented by combining variational inference framework with deep learning. Optical synthetic aperture with homogeneous circular sub-mirrors greatly improves the spatial resolution of space telescopes; however, the discrete and sparse characteristics of the sub-mirrors reduce the mid-frequency modulation transfer function (MTF), resulting in blurred images being obtained. In this paper, a method combining variational physics-informed with deep learning is presented, which shows blind image restoration without complex priors. The constraint effect of traditional maximum a posterior (MAP) framework is removed by variational inference framework, which is embedded into Variational Physics-informed Network (VPIN) to optimize neural network training. Residual dense blocks (RDBs) construction is contributed to image feature extraction. Networks with SSIM-corrected loss functions can be trained at the feature level to help with convergence. When SNR = 30 dB, the PSNR of Golay-6 remote sensing test set increases from 20.16 dB to 23.90 dB, SSIM is from 0.610 to 0.842, and MS-SSIM is from 0.930 to 0.955. [ABSTRACT FROM AUTHOR]

Published

2023