Litcius/Paper detail

Knowledge Graph-Enhanced Sampling for Conversational Recommendation System

Mengyuan Zhao, Xiaowen Huang, Lixi Zhu, Jitao Sang, Jian Yu

2022IEEE Transactions on Knowledge and Data Engineering14 citationsDOI

Abstract

The traditional recommendation systems mainly use offline user data to train offline models, and then recommend items for online users, thus suffering from the unreliable estimation of user preferences based on sparse and noisy historical data. Conversational Recommendation System(CRS) uses the interactive form of the dialogue systems to solve the intrinsic problems of traditional recommendation systems. However, due to the lack of contextual information modeling, the existing CRS models are unable to deal with the exploitation and exploration(E&E) problem well, resulting in the heavy burden on users. To address the aforementioned issue, this work proposes a contextual information enhancement model tailored for CRS, called Knowledge Graph-enhanced Sampling(KGenSam). KGenSam integrates the dynamic graph of user interaction data with the external knowledge into one heterogeneous Knowledge Graph(KG) as the contextual information environment. Then, two samplers are designed to enhance knowledge by sampling fuzzy samples with high uncertainty for obtaining user preferences and reliable negative samples for updating recommender to achieve efficient acquisition of user preferences and model updating, and thus provide a powerful solution for CRS to deal with E&E problem. Experimental results on two real-world datasets demonstrate the superiority of KGenSam with significant improvements over state-of-the-art methods.

Topics & Concepts

Computer scienceRecommender systemKnowledge graphGraphData miningSampling (signal processing)User modelingMachine learningInformation retrievalArtificial intelligenceHuman–computer interactionUser interfaceTheoretical computer scienceFilter (signal processing)Computer visionOperating systemRecommender Systems and TechniquesAdvanced Graph Neural NetworksTopic Modeling