Clustering via adaptive and locality-constrained graph learning and unsupervised ELM
In this paper an effective graph learning method is proposed for clustering based on adaptive graph regularizations. Many graph learning methods focus on optimizing a global constraint on sparsity, low-rankness or weighted pair-wise distances, but they often fail to consider local connectivities. We...
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sg-ntu-dr.10356-1609692022-08-10T01:22:13Z Clustering via adaptive and locality-constrained graph learning and unsupervised ELM Zeng, Yijie Chen, Jichao Li, Yue Qing, Yuanyuan Huang, Guang-Bin School of Electrical and Electronic Engineering Engineering::Electrical and electronic engineering Graph Learning Clustering In this paper an effective graph learning method is proposed for clustering based on adaptive graph regularizations. Many graph learning methods focus on optimizing a global constraint on sparsity, low-rankness or weighted pair-wise distances, but they often fail to consider local connectivities. We demonstrate the importance of locality by generalizing the Locality-constrained Linear Coding (LLC) for unsupervised learning. Each data sample is expressed as a representation of its nearest neighbors, which naturally leads to a combination of distance regularized features and a Locally Linear Embedding (LLE) decomposition. The representation enforces a locally sparse connection on the data graph that exhibits high discrimination power and is easy to optimize. To improve the learned graph structure and incorporate cluster information, a rank constraint is further imposed on the Laplacian matrix of the data graph so that the connected components match the class number. The obtained representations are smoothed via manifold regularizations on a predefined graph which serves as a prior for graph learning. Finally, we utilize unsupervised Extreme Learning Machine (US-ELM) to learn a flexible and discriminative data embedding. Extensive evaluations show that the proposed algorithm outperforms graph learning counterpart methods on a wide range of benchmark datasets. 2022-08-10T01:22:13Z 2022-08-10T01:22:13Z 2020 Journal Article Zeng, Y., Chen, J., Li, Y., Qing, Y. & Huang, G. (2020). Clustering via adaptive and locality-constrained graph learning and unsupervised ELM. Neurocomputing, 401, 224-235. https://dx.doi.org/10.1016/j.neucom.2020.03.045 0925-2312 https://hdl.handle.net/10356/160969 10.1016/j.neucom.2020.03.045 2-s2.0-85083063990 401 224 235 en Neurocomputing © 2020 Elsevier B.V. All rights reserved. |
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Engineering::Electrical and electronic engineering Graph Learning Clustering Zeng, Yijie Chen, Jichao Li, Yue Qing, Yuanyuan Huang, Guang-Bin Clustering via adaptive and locality-constrained graph learning and unsupervised ELM |
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In this paper an effective graph learning method is proposed for clustering based on adaptive graph regularizations. Many graph learning methods focus on optimizing a global constraint on sparsity, low-rankness or weighted pair-wise distances, but they often fail to consider local connectivities. We demonstrate the importance of locality by generalizing the Locality-constrained Linear Coding (LLC) for unsupervised learning. Each data sample is expressed as a representation of its nearest neighbors, which naturally leads to a combination of distance regularized features and a Locally Linear Embedding (LLE) decomposition. The representation enforces a locally sparse connection on the data graph that exhibits high discrimination power and is easy to optimize. To improve the learned graph structure and incorporate cluster information, a rank constraint is further imposed on the Laplacian matrix of the data graph so that the connected components match the class number. The obtained representations are smoothed via manifold regularizations on a predefined graph which serves as a prior for graph learning. Finally, we utilize unsupervised Extreme Learning Machine (US-ELM) to learn a flexible and discriminative data embedding. Extensive evaluations show that the proposed algorithm outperforms graph learning counterpart methods on a wide range of benchmark datasets. |
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School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Zeng, Yijie Chen, Jichao Li, Yue Qing, Yuanyuan Huang, Guang-Bin |
| format |
Article |
| author |
Zeng, Yijie Chen, Jichao Li, Yue Qing, Yuanyuan Huang, Guang-Bin |
| author_sort |
Zeng, Yijie |
| title |
Clustering via adaptive and locality-constrained graph learning and unsupervised ELM |
| title_short |
Clustering via adaptive and locality-constrained graph learning and unsupervised ELM |
| title_full |
Clustering via adaptive and locality-constrained graph learning and unsupervised ELM |
| title_fullStr |
Clustering via adaptive and locality-constrained graph learning and unsupervised ELM |
| title_full_unstemmed |
Clustering via adaptive and locality-constrained graph learning and unsupervised ELM |
| title_sort |
clustering via adaptive and locality-constrained graph learning and unsupervised elm |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/160969 |
| _version_ |
1743119467212177408 |