Your search keyword '"Paquet, Ulrich"' showing total 5 results

1. A Disentangled Recognition and Nonlinear Dynamics Model for Unsupervised Learning

Author

Fraccaro, Marco, Kamronn, Simon, Paquet, Ulrich, and Winther, Ole

Subjects

Statistics - Machine Learning, Computer Science - Learning

Abstract

This paper takes a step towards temporal reasoning in a dynamically changing video, not in the pixel space that constitutes its frames, but in a latent space that describes the non-linear dynamics of the objects in its world. We introduce the Kalman variational auto-encoder, a framework for unsupervised learning of sequential data that disentangles two latent representations: an object's representation, coming from a recognition model, and a latent state describing its dynamics. As a result, the evolution of the world can be imagined and missing data imputed, both without the need to generate high dimensional frames at each time step. The model is trained end-to-end on videos of a variety of simulated physical systems, and outperforms competing methods in generative and missing data imputation tasks., Comment: NIPS 2017

Published

2017

2. The Bayesian Low-Rank Determinantal Point Process Mixture Model

Author

Gartrell, Mike, Paquet, Ulrich, and Koenigstein, Noam

Subjects

Statistics - Machine Learning, Computer Science - Learning

Abstract

Determinantal point processes (DPPs) are an elegant model for encoding probabilities over subsets, such as shopping baskets, of a ground set, such as an item catalog. They are useful for a number of machine learning tasks, including product recommendation. DPPs are parametrized by a positive semi-definite kernel matrix. Recent work has shown that using a low-rank factorization of this kernel provides remarkable scalability improvements that open the door to training on large-scale datasets and computing online recommendations, both of which are infeasible with standard DPP models that use a full-rank kernel. In this paper we present a low-rank DPP mixture model that allows us to represent the latent structure present in observed subsets as a mixture of a number of component low-rank DPPs, where each component DPP is responsible for representing a portion of the observed data. The mixture model allows us to effectively address the capacity constraints of the low-rank DPP model. We present an efficient and scalable Markov Chain Monte Carlo (MCMC) learning algorithm for our model that uses Gibbs sampling and stochastic gradient Hamiltonian Monte Carlo (SGHMC). Using an evaluation on several real-world product recommendation datasets, we show that our low-rank DPP mixture model provides substantially better predictive performance than is possible with a single low-rank or full-rank DPP, and significantly better performance than several other competing recommendation methods in many cases., Comment: 9 pages, 6 figures. This article draws heavily from arXiv:1602.05436

Published

2016

3. Sequential Neural Models with Stochastic Layers

Author

Fraccaro, Marco, Sønderby, Søren Kaae, Paquet, Ulrich, and Winther, Ole

Subjects

Statistics - Machine Learning, Computer Science - Learning

Abstract

How can we efficiently propagate uncertainty in a latent state representation with recurrent neural networks? This paper introduces stochastic recurrent neural networks which glue a deterministic recurrent neural network and a state space model together to form a stochastic and sequential neural generative model. The clear separation of deterministic and stochastic layers allows a structured variational inference network to track the factorization of the model's posterior distribution. By retaining both the nonlinear recursive structure of a recurrent neural network and averaging over the uncertainty in a latent path, like a state space model, we improve the state of the art results on the Blizzard and TIMIT speech modeling data sets by a large margin, while achieving comparable performances to competing methods on polyphonic music modeling., Comment: NIPS 2016

Published

2016

4. Low-Rank Factorization of Determinantal Point Processes for Recommendation

Author

Gartrell, Mike, Paquet, Ulrich, and Koenigstein, Noam

Subjects

Statistics - Machine Learning, Computer Science - Learning

Abstract

Determinantal point processes (DPPs) have garnered attention as an elegant probabilistic model of set diversity. They are useful for a number of subset selection tasks, including product recommendation. DPPs are parametrized by a positive semi-definite kernel matrix. In this work we present a new method for learning the DPP kernel from observed data using a low-rank factorization of this kernel. We show that this low-rank factorization enables a learning algorithm that is nearly an order of magnitude faster than previous approaches, while also providing for a method for computing product recommendation predictions that is far faster (up to 20x faster or more for large item catalogs) than previous techniques that involve a full-rank DPP kernel. Furthermore, we show that our method provides equivalent or sometimes better predictive performance than prior full-rank DPP approaches, and better performance than several other competing recommendation methods in many cases. We conduct an extensive experimental evaluation using several real-world datasets in the domain of product recommendation to demonstrate the utility of our method, along with its limitations., Comment: 10 pages, 4 figures. Submitted to KDD 2016

Published

2016

5. One-class Collaborative Filtering with Random Graphs: Annotated Version

Author

Paquet, Ulrich and Koenigstein, Noam

Subjects

Statistics - Machine Learning, Computer Science - Learning, G.3

Abstract

The bane of one-class collaborative filtering is interpreting and modelling the latent signal from the missing class. In this paper we present a novel Bayesian generative model for implicit collaborative filtering. It forms a core component of the Xbox Live architecture, and unlike previous approaches, delineates the odds of a user disliking an item from simply not considering it. The latent signal is treated as an unobserved random graph connecting users with items they might have encountered. We demonstrate how large-scale distributed learning can be achieved through a combination of stochastic gradient descent and mean field variational inference over random graph samples. A fine-grained comparison is done against a state of the art baseline on real world data., Comment: 11 pages, 7 figures. Detailed, annotated and expanded version of conference paper "One-class Collaborative Filtering with Random Graphs" (WWW 2013)

Published

2013