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Denoising Heterogeneous Graph Pre-training Framework for Recommendation.

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Názov: Denoising Heterogeneous Graph Pre-training Framework for Recommendation.
Autori: Sang, Lei, Wang, Yu, Zhang, Yiwen, Wu, Xindong
Zdroj: ACM Transactions on Information Systems; Sep2025, Vol. 43 Issue 5, p1-31, 31p
Predmety: GRAPH neural networks, INFORMATION filtering, SOURCE code, INFORMATION processing, SEMANTICS, RECOMMENDER systems
Abstrakt: Heterogeneous graph neural networks (HGNN) have exhibited significant performance gains by modeling the information propagation process in graph-structured data for recommender systems. However, existing HGNN-based Recommendation still face two challenges: (1) They overlook the rich semantics brought by the combination of different meta-paths, making it difficult to capture the importance of various meta-paths; (2) when HGNN use meta-paths to capture high-order information, they are susceptible to noise data, as noise from connected nodes can create cumulative effects on a target node in the graph. To tackle these issues, we propose a new model called the Denoising Heterogeneous Graph Pre-training Framework (DHGPF) to enhance recommendation tasks. This framework has two stages: pre-training and training. In the pre-training stage, we assign learnable weights to different meta-paths and use a simplified multi-layer graph convolution network to automatically aggregate semantic information from different meta-path combinations. This approach can capture the importance of these paths. The training stage focuses on reducing noise using gating mechanism and denoising structure learning methods. These methods accomplish the denoising process through information filtering. Our model was evaluated on three real-world datasets, demonstrating that DHGPF outperforms other state-of-the-art recommendation methods. We have further organized the source code of the article at https://github.com/wangyu0627/DHGPF. [ABSTRACT FROM AUTHOR]
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Databáza: Complementary Index
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Abstrakt:Heterogeneous graph neural networks (HGNN) have exhibited significant performance gains by modeling the information propagation process in graph-structured data for recommender systems. However, existing HGNN-based Recommendation still face two challenges: (1) They overlook the rich semantics brought by the combination of different meta-paths, making it difficult to capture the importance of various meta-paths; (2) when HGNN use meta-paths to capture high-order information, they are susceptible to noise data, as noise from connected nodes can create cumulative effects on a target node in the graph. To tackle these issues, we propose a new model called the Denoising Heterogeneous Graph Pre-training Framework (DHGPF) to enhance recommendation tasks. This framework has two stages: pre-training and training. In the pre-training stage, we assign learnable weights to different meta-paths and use a simplified multi-layer graph convolution network to automatically aggregate semantic information from different meta-path combinations. This approach can capture the importance of these paths. The training stage focuses on reducing noise using gating mechanism and denoising structure learning methods. These methods accomplish the denoising process through information filtering. Our model was evaluated on three real-world datasets, demonstrating that DHGPF outperforms other state-of-the-art recommendation methods. We have further organized the source code of the article at https://github.com/wangyu0627/DHGPF. [ABSTRACT FROM AUTHOR]
ISSN:10468188
DOI:10.1145/3706632