Collaborative Filtering (CF) has emerged as fundamental paradigms for parameterizing users and items into latent representation space, with their correlative patterns from interaction data. Among various CF techniques, the development of GNN-based recommender systems, e.g., PinSage and LightGCN, has offered the state-of-the-art performance. However, two key challenges have not been well explored in existing solutions: i) The over-smoothing effect with deeper graph-based CF architecture, may cause the indistinguishable user representations and degradation of recommendation results. ii) The supervision signals (i.e., user-item interactions) are usually scarce and skewed distributed in reality, which limits the representation power of CF paradigms. To tackle these challenges, we propose a new self-supervised recommendation framework Hypergraph Contrastive Collaborative Filtering (HCCF) to jointly capture local and global collaborative relations with a hypergraph-enhanced cross-view contrastive learning architecture. In particular, the designed hypergraph structure learning enhances the discrimination ability of GNN-based CF paradigm, in comprehensively capturing the complex high-order dependencies among users. Additionally, our HCCF model effectively integrates the hypergraph structure encoding with self-supervised learning to reinforce the representation quality of recommender systems, based on the hypergraph self-discrimination. Extensive experiments on three benchmark datasets demonstrate the superiority of our model over various state-of-the-art recommendation methods, and the robustness against sparse user interaction data. The implementation codes are available at https://github.com/akaxlh/HCCF.
翻译:协作过滤(CF)是将用户和物品纳入潜在代表空间的参数化的基本范例,其相关模式来自互动数据; 在各种CF技术中,开发基于GNN的推荐系统,例如PinSage和LightGCN, 提供了最先进的绩效;然而,现有解决方案中尚未充分探讨两项关键挑战:(一) 更深的图形化CF结构的过度移动效应可能导致无法区分的用户表达和建议结果的退化。 (二) 监督信号(即用户项目互动)通常稀缺,在现实中分布偏斜,限制了基于GNNN的推荐系统,例如PinSage和LightGCN, 提供了最先进的业绩;然而,为了应对这些挑战,我们提出了一个新的自我监督建议框架,即超光速对比协作过滤(HCCF),以联合捕捉与超光速增强的交叉对比学习结构的当地和全球协作关系。 特别是,设计的国家结构学习加强了基于GNNM-C-CF的准确性互动能力,在全面整合HCF-Slimatealimal 的自我代表结构中,在全面整合基于高层次的自我分析的自我分析结构的自我分析系统的基础上, 基础学习系统,取决于基础系统,我们的三个系统, 基础系统基础的系统,以强化的学习系统。