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Scalable Bayesian Non-linear Matrix Completion

arXiv:1908.01009

summary

The paper proposes a scalable Bayesian algorithm for non‑linear matrix completion using Gaussian process latent variable models and a data‑parallel distributed implementation.

Abstract

Matrix completion aims to predict missing elements in a partially observed data matrix which in typical applications, such as collaborative filtering, is large and extremely sparsely observed. A standard solution is matrix factorization, which predicts unobserved entries as linear combinations of latent variables. We generalize to non-linear combinations in massive-scale matrices. Bayesian approaches have been proven beneficial in linear matrix completion, but not applied in the more general non-linear case, due to limited scalability. We introduce a Bayesian non-linear matrix completion algorithm, which is based on a recent Bayesian formulation of Gaussian process latent variable models. To solve the challenges regarding scalability and computation, we propose a data-parallel distributed computational approach with a restricted communication scheme. We evaluate our method on challenging out-of-matrix prediction tasks using both simulated and real-world data.

7 pages, 1 figures, 2 tables. The paper has been accepted for publication in the proceedings of the 28th International Joint Conference on Artificial Intelligence (IJCAI 2019)

Topics & keywords

#matrix completion#bayesian inference#nonlinear models#distributed computing#gaussian processesGaussian process latent variable modeldata‑parallel algorithmrestricted communication schemeout‑of‑matrix predictionscalable Bayesian inference