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Autori principali: Lu, Ruiying, Cheng, Ziheng, Chen, Bo, Yuan, Xin
Natura: Preprint
Pubblicazione: 2022
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Accesso online:https://arxiv.org/abs/2203.00387
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author Lu, Ruiying
Cheng, Ziheng
Chen, Bo
Yuan, Xin
author_facet Lu, Ruiying
Cheng, Ziheng
Chen, Bo
Yuan, Xin
contents Video snapshot compressive imaging (SCI) utilizes a 2D detector to capture sequential video frames and compress them into a single measurement. Various reconstruction methods have been developed to recover the high-speed video frames from the snapshot measurement. However, most existing reconstruction methods are incapable of efficiently capturing long-range spatial and temporal dependencies, which are critical for video processing. In this paper, we propose a flexible and robust approach based on the graph neural network (GNN) to efficiently model non-local interactions between pixels in space and time regardless of the distance. Specifically, we develop a motion-aware dynamic GNN for better video representation, i.e., represent each node as the aggregation of relative neighbors under the guidance of frame-by-frame motions, which consists of motion-aware dynamic sampling, cross-scale node sampling, global knowledge integration, and graph aggregation. Extensive results on both simulation and real data demonstrate both the effectiveness and efficiency of the proposed approach, and the visualization illustrates the intrinsic dynamic sampling operations of our proposed model for boosting the video SCI reconstruction results. The code and model will be released.
format Preprint
id arxiv_https___arxiv_org_abs_2203_00387
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Motion-aware Dynamic Graph Neural Network for Video Compressive Sensing
Lu, Ruiying
Cheng, Ziheng
Chen, Bo
Yuan, Xin
Computer Vision and Pattern Recognition
Video snapshot compressive imaging (SCI) utilizes a 2D detector to capture sequential video frames and compress them into a single measurement. Various reconstruction methods have been developed to recover the high-speed video frames from the snapshot measurement. However, most existing reconstruction methods are incapable of efficiently capturing long-range spatial and temporal dependencies, which are critical for video processing. In this paper, we propose a flexible and robust approach based on the graph neural network (GNN) to efficiently model non-local interactions between pixels in space and time regardless of the distance. Specifically, we develop a motion-aware dynamic GNN for better video representation, i.e., represent each node as the aggregation of relative neighbors under the guidance of frame-by-frame motions, which consists of motion-aware dynamic sampling, cross-scale node sampling, global knowledge integration, and graph aggregation. Extensive results on both simulation and real data demonstrate both the effectiveness and efficiency of the proposed approach, and the visualization illustrates the intrinsic dynamic sampling operations of our proposed model for boosting the video SCI reconstruction results. The code and model will be released.
title Motion-aware Dynamic Graph Neural Network for Video Compressive Sensing
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2203.00387