Your search keyword '"Sutskever I"' showing total 4 results

1. Improving Variational Autoencoders with Inverse Autoregressive Flow

Author

Kingma, D., Salimans, T., Josefowicz, R., Chen, X., Sutskever, I., Welling, M., Lee, D.D., von Luxburg, U., Garnett, R., Sugiyama, M., Guyon, I., and Amsterdam Machine Learning lab (IVI, FNWI)

Abstract

The framework of normalizing flows provides a general strategy for flexible variational inference of posteriors over latent variables. We propose a new type of normalizing flow, inverse autoregressive flow (IAF), that, in contrast to earlier published flows, scales well to high-dimensional latent spaces. The proposed flow consists of a chain of invertible transformations, where each transformation is based on an autoregressive neural network. In experiments, we show that IAF significantly improves upon diagonal Gaussian approximate posteriors. In addition, we demonstrate that a novel type of variational autoencoder, coupled with IAF, is competitive with neural autoregressive models in terms of attained log-likelihood on natural images, while allowing significantly faster synthesis.

Published

2017

2. Mastering the game of Go with deep neural networks and tree search.

Author

Silver D, Huang A, Maddison CJ, Guez A, Sifre L, van den Driessche G, Schrittwieser J, Antonoglou I, Panneershelvam V, Lanctot M, Dieleman S, Grewe D, Nham J, Kalchbrenner N, Sutskever I, Lillicrap T, Leach M, Kavukcuoglu K, Graepel T, and Hassabis D

Subjects

Computers, Europe, Humans, Monte Carlo Method, Reinforcement, Psychology, Games, Recreational, Neural Networks, Computer, Software, Supervised Machine Learning

Abstract

The game of Go has long been viewed as the most challenging of classic games for artificial intelligence owing to its enormous search space and the difficulty of evaluating board positions and moves. Here we introduce a new approach to computer Go that uses 'value networks' to evaluate board positions and 'policy networks' to select moves. These deep neural networks are trained by a novel combination of supervised learning from human expert games, and reinforcement learning from games of self-play. Without any lookahead search, the neural networks play Go at the level of state-of-the-art Monte Carlo tree search programs that simulate thousands of random games of self-play. We also introduce a new search algorithm that combines Monte Carlo simulation with value and policy networks. Using this search algorithm, our program AlphaGo achieved a 99.8% winning rate against other Go programs, and defeated the human European Go champion by 5 games to 0. This is the first time that a computer program has defeated a human professional player in the full-sized game of Go, a feat previously thought to be at least a decade away.

Published

2016

3. Temporal-kernel recurrent neural networks.

Author

Sutskever I and Hinton G

Subjects

Algorithms, Humans, Neuropsychological Tests, Time Factors, Memory, Short-Term, Neural Networks, Computer

Abstract

A Recurrent Neural Network (RNN) is a powerful connectionist model that can be applied to many challenging sequential problems, including problems that naturally arise in language and speech. However, RNNs are extremely hard to train on problems that have long-term dependencies, where it is necessary to remember events for many timesteps before using them to make a prediction. In this paper we consider the problem of training RNNs to predict sequences that exhibit significant long-term dependencies, focusing on a serial recall task where the RNN needs to remember a sequence of characters for a large number of steps before reconstructing it. We introduce the Temporal-Kernel Recurrent Neural Network (TKRNN), which is a variant of the RNN that can cope with long-term dependencies much more easily than a standard RNN, and show that the TKRNN develops short-term memory that successfully solves the serial recall task by representing the input string with a stable state of its hidden units., (Copyright 2009 Elsevier Ltd. All rights reserved.)

Published

2010

4. Deep, narrow sigmoid belief networks are universal approximators.

Author

Sutskever I and Hinton GE

Subjects

Algorithms, Humans, Nonlinear Dynamics, Learning, Neural Networks, Computer

Abstract

In this note, we show that exponentially deep belief networks can approximate any distribution over binary vectors to arbitrary accuracy, even when the width of each layer is limited to the dimensionality of the data. We further show that such networks can be greedily learned in an easy yet impractical way.

Published

2008