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Autores principales: Ding, Yao, Kang, Weijie, Yang, Aitao, Zhang, Zhili, Zhao, Junyang, Feng, Jie, Hong, Danfeng, Zheng, Qinhe
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2501.01595
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author Ding, Yao
Kang, Weijie
Yang, Aitao
Zhang, Zhili
Zhao, Junyang
Feng, Jie
Hong, Danfeng
Zheng, Qinhe
author_facet Ding, Yao
Kang, Weijie
Yang, Aitao
Zhang, Zhili
Zhao, Junyang
Feng, Jie
Hong, Danfeng
Zheng, Qinhe
contents Hyperspectral image (HSI) clustering has been a fundamental but challenging task with zero training labels. Currently, some deep graph clustering methods have been successfully explored for HSI due to their outstanding performance in effective spatial structural information encoding. Nevertheless, insufficient structural information utilization, poor feature presentation ability, and weak graph update capability limit their performance. Thus, in this paper, a homophily structure graph learning with an adaptive filter clustering method (AHSGC) for HSI is proposed. Specifically, homogeneous region generation is first developed for HSI processing and constructing the original graph. Afterward, an adaptive filter graph encoder is designed to adaptively capture the high and low frequency features on the graph for subsequence processing. Then, a graph embedding clustering self-training decoder is developed with KL Divergence, with which the pseudo-label is generated for network training. Meanwhile, homophily-enhanced structure learning is introduced to update the graph according to the clustering task, in which the orient correlation estimation is adopted to estimate the node connection, and graph edge sparsification is designed to adjust the edges in the graph dynamically. Finally, a joint network optimization is introduced to achieve network self-training and update the graph. The K-means is adopted to express the latent features. Extensive experiments and repeated comparative analysis have verified that our AHSGC contains high clustering accuracy, low computational complexity, and strong robustness. The code source will be available at https://github.com/DY-HYX.
format Preprint
id arxiv_https___arxiv_org_abs_2501_01595
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Adaptive Homophily Clustering: Structure Homophily Graph Learning with Adaptive Filter for Hyperspectral Image
Ding, Yao
Kang, Weijie
Yang, Aitao
Zhang, Zhili
Zhao, Junyang
Feng, Jie
Hong, Danfeng
Zheng, Qinhe
Computer Vision and Pattern Recognition
Hyperspectral image (HSI) clustering has been a fundamental but challenging task with zero training labels. Currently, some deep graph clustering methods have been successfully explored for HSI due to their outstanding performance in effective spatial structural information encoding. Nevertheless, insufficient structural information utilization, poor feature presentation ability, and weak graph update capability limit their performance. Thus, in this paper, a homophily structure graph learning with an adaptive filter clustering method (AHSGC) for HSI is proposed. Specifically, homogeneous region generation is first developed for HSI processing and constructing the original graph. Afterward, an adaptive filter graph encoder is designed to adaptively capture the high and low frequency features on the graph for subsequence processing. Then, a graph embedding clustering self-training decoder is developed with KL Divergence, with which the pseudo-label is generated for network training. Meanwhile, homophily-enhanced structure learning is introduced to update the graph according to the clustering task, in which the orient correlation estimation is adopted to estimate the node connection, and graph edge sparsification is designed to adjust the edges in the graph dynamically. Finally, a joint network optimization is introduced to achieve network self-training and update the graph. The K-means is adopted to express the latent features. Extensive experiments and repeated comparative analysis have verified that our AHSGC contains high clustering accuracy, low computational complexity, and strong robustness. The code source will be available at https://github.com/DY-HYX.
title Adaptive Homophily Clustering: Structure Homophily Graph Learning with Adaptive Filter for Hyperspectral Image
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2501.01595