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Searching to Sparsify Tensor Decomposition for N-ary Relational Data

Shimin Di, Quanming Yao, Lei Chen

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Abstract

Tensor, an extension of the vector and matrix to the multi-dimensional case, is a natural way to describe the N-ary relational data. Recently, tensor decomposition methods have been introduced into N-ary relational data and become state-of-the-art on embedding learning. However, the performance of existing tensor decomposition methods is not as good as desired. First, they suffer from the data-sparsity issue since they can only learn from the N-ary relational data with a specific arity, i.e., parts of common N-ary relational data. Besides, they are neither effective nor efficient enough to be trained due to the over-parameterization problem. In this paper, we propose a novel method, i.e., S2S, for effectively and efficiently learning from the N-ary relational data. Specifically, we propose a new tensor decomposition framework, which allows embedding sharing to learn from facts with mixed arity. Since the core tensors may still suffer from the over-parameterization, we propose to reduce parameters by sparsifying the core tensors while retaining their expressive power using neural architecture search (NAS) techniques, which can search for data-dependent architectures. As a result, the proposed S2S not only guarantees to be expressive but also efficiently learns from mixed arity. Finally, empirical results have demonstrated that S2S is efficient to train and achieves state-of-the-art performance. 1

Topics & Concepts

ArityTensor (intrinsic definition)EmbeddingComputer scienceTucker decompositionRelational databaseDecompositionTheoretical computer scienceStatistical relational learningArtificial neural networkMatrix decompositionArtificial intelligenceData miningAlgorithmTensor decompositionMathematicsDiscrete mathematicsBiologyPhysicsQuantum mechanicsEcologyEigenvalues and eigenvectorsPure mathematicsTensor decomposition and applicationsAdvanced Graph Neural NetworksRecommender Systems and Techniques