Dynamic Poisson Factorization
September 15, 2015 ยท Declared Dead ยท ๐ ACM Conference on Recommender Systems
"No code URL or promise found in abstract"
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Authors
Laurent Charlin, Rajesh Ranganath, James McInerney, David M. Blei
arXiv ID
1509.04640
Category
cs.LG: Machine Learning
Cross-listed
cs.IR,
stat.ML
Citations
104
Venue
ACM Conference on Recommender Systems
Last Checked
4 months ago
Abstract
Models for recommender systems use latent factors to explain the preferences and behaviors of users with respect to a set of items (e.g., movies, books, academic papers). Typically, the latent factors are assumed to be static and, given these factors, the observed preferences and behaviors of users are assumed to be generated without order. These assumptions limit the explorative and predictive capabilities of such models, since users' interests and item popularity may evolve over time. To address this, we propose dPF, a dynamic matrix factorization model based on the recent Poisson factorization model for recommendations. dPF models the time evolving latent factors with a Kalman filter and the actions with Poisson distributions. We derive a scalable variational inference algorithm to infer the latent factors. Finally, we demonstrate dPF on 10 years of user click data from arXiv.org, one of the largest repository of scientific papers and a formidable source of information about the behavior of scientists. Empirically we show performance improvement over both static and, more recently proposed, dynamic recommendation models. We also provide a thorough exploration of the inferred posteriors over the latent variables.
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