Learning to do multiframe wavefront sensing unsupervised: Applications to blind deconvolution

反褶积 盲反褶积 人工智能 先验与后验 人工神经网络 计算机科学 波前 计算机视觉 自适应光学 算法 图像复原 物理 深度学习 点扩散函数 图像处理 泽尼克多项式 图像(数学) 功能(生物学) 维纳反褶积 迭代重建 光学 光传递函数 方案(数学) 概率逻辑 模式识别(心理学) 监督学习 图像分辨率
作者
A. Asensio Ramos,N. Olspert
出处
期刊:Astronomy and Astrophysics [EDP Sciences]
卷期号:646: A100-A100 被引量:17
标识
DOI:10.1051/0004-6361/202038552
摘要

Context. Observations from ground-based telescopes are severely perturbed by the presence of the Earth’s atmosphere. The use of adaptive optics techniques has allowed us to partly overcome this limitation. However, image-selection or post-facto image-reconstruction methods applied to bursts of short-exposure images are routinely needed to reach the diffraction limit. Deep learning has recently been proposed as an efficient way to accelerate these image reconstructions. Currently, these deep neural networks are trained with supervision, meaning that either standard deconvolution algorithms need to be applied a priori or complex simulations of the solar magneto-convection need to be carried out to generate the training sets. Aims. Our aim here is to propose a general unsupervised training scheme that allows multiframe blind deconvolution deep learning systems to be trained with observations only. The approach can be applied for the correction of point-like as well as extended objects. Methods. Leveraging the linear image formation theory and a probabilistic approach to the blind deconvolution problem produces a physically motivated loss function. Optimization of this loss function allows end-to-end training of a machine learning model composed of three neural networks. Results. As examples, we apply this procedure to the deconvolution of stellar data from the FastCam instrument and to solar extended data from the Swedish Solar Telescope. The analysis demonstrates that the proposed neural model can be successfully trained without supervision using observations only. It provides estimations of the instantaneous wavefronts, from which a corrected image can be found using standard deconvolution techniques. The network model is roughly three orders of magnitude faster than applying standard deconvolution based on optimization and shows potential to be used on real-time at the telescope.
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