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END4Rec: Efficient Noise-Decoupling for Multi-Behavior Sequential Recommendation

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arxiv 2403.17603 v1 pith:UCYQVD7Y submitted 2024-03-26 cs.IR

END4Rec: Efficient Noise-Decoupling for Multi-Behavior Sequential Recommendation

classification cs.IR
keywords behaviorrecommendationdatanoiseuserbehaviorsdenoisingefficiency
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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In recommendation systems, users frequently engage in multiple types of behaviors, such as clicking, adding to a cart, and purchasing. However, with diversified behavior data, user behavior sequences will become very long in the short term, which brings challenges to the efficiency of the sequence recommendation model. Meanwhile, some behavior data will also bring inevitable noise to the modeling of user interests. To address the aforementioned issues, firstly, we develop the Efficient Behavior Sequence Miner (EBM) that efficiently captures intricate patterns in user behavior while maintaining low time complexity and parameter count. Secondly, we design hard and soft denoising modules for different noise types and fully explore the relationship between behaviors and noise. Finally, we introduce a contrastive loss function along with a guided training strategy to compare the valid information in the data with the noisy signal, and seamlessly integrate the two denoising processes to achieve a high degree of decoupling of the noisy signal. Sufficient experiments on real-world datasets demonstrate the effectiveness and efficiency of our approach in dealing with multi-behavior sequential recommendation.

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