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Collaboration-Aware Graph Convolutional Network for Recommender Systems

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arxiv 2207.06221 v4 pith:NIRKSLU3 submitted 2022-07-03 cs.IR cs.LG

Collaboration-Aware Graph Convolutional Network for Recommender Systems

classification cs.IR cs.LG
keywords cagcncollaborativeeffectgraphmessage-passingcapturescollaboration-awareconvolutional
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Graph Neural Networks (GNNs) have been successfully adopted in recommender systems by virtue of the message-passing that implicitly captures collaborative effect. Nevertheless, most of the existing message-passing mechanisms for recommendation are directly inherited from GNNs without scrutinizing whether the captured collaborative effect would benefit the prediction of user preferences. In this paper, we first analyze how message-passing captures the collaborative effect and propose a recommendation-oriented topological metric, Common Interacted Ratio (CIR), which measures the level of interaction between a specific neighbor of a node with the rest of its neighbors. After demonstrating the benefits of leveraging collaborations from neighbors with higher CIR, we propose a recommendation-tailored GNN, Collaboration-Aware Graph Convolutional Network (CAGCN), that goes beyond 1-Weisfeiler-Lehman(1-WL) test in distinguishing non-bipartite-subgraph-isomorphic graphs. Experiments on six benchmark datasets show that the best CAGCN variant outperforms the most representative GNN-based recommendation model, LightGCN, by nearly 10% in Recall@20 and also achieves around 80% speedup. Our code is publicly available at https://github.com/YuWVandy/CAGCN.

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