Your search keyword '"Sepassi, Ryan"' showing total 4 results

1. Model-Based Reinforcement Learning for Atari

Author

Kaiser, Lukasz, Babaeizadeh, Mohammad, Milos, Piotr, Osinski, Blazej, Campbell, Roy H, Czechowski, Konrad, Erhan, Dumitru, Finn, Chelsea, Kozakowski, Piotr, Levine, Sergey, Mohiuddin, Afroz, Sepassi, Ryan, Tucker, George, and Michalewski, Henryk

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Machine Learning, Machine Learning (stat.ML), Machine Learning (cs.LG)

Abstract

Model-free reinforcement learning (RL) can be used to learn effective policies for complex tasks, such as Atari games, even from image observations. However, this typically requires very large amounts of interaction -- substantially more, in fact, than a human would need to learn the same games. How can people learn so quickly? Part of the answer may be that people can learn how the game works and predict which actions will lead to desirable outcomes. In this paper, we explore how video prediction models can similarly enable agents to solve Atari games with fewer interactions than model-free methods. We describe Simulated Policy Learning (SimPLe), a complete model-based deep RL algorithm based on video prediction models and present a comparison of several model architectures, including a novel architecture that yields the best results in our setting. Our experiments evaluate SimPLe on a range of Atari games in low data regime of 100k interactions between the agent and the environment, which corresponds to two hours of real-time play. In most games SimPLe outperforms state-of-the-art model-free algorithms, in some games by over an order of magnitude.

Published

2019

2. Generating Wikipedia by Summarizing Long Sequences

Author

Liu, Peter J., Saleh, Mohammad, Pot, Etienne, Goodrich, Ben, Sepassi, Ryan, Kaiser, Lukasz, and Shazeer, Noam

Subjects

FOS: Computer and information sciences, Computer Science - Computation and Language, Computation and Language (cs.CL)

Abstract

We show that generating English Wikipedia articles can be approached as a multi- document summarization of source documents. We use extractive summarization to coarsely identify salient information and a neural abstractive model to generate the article. For the abstractive model, we introduce a decoder-only architecture that can scalably attend to very long sequences, much longer than typical encoder- decoder architectures used in sequence transduction. We show that this model can generate fluent, coherent multi-sentence paragraphs and even whole Wikipedia articles. When given reference documents, we show it can extract relevant factual information as reflected in perplexity, ROUGE scores and human evaluations., Comment: Published as a conference paper at ICLR 2018

Published

2018

3. Tensor2Tensor for Neural Machine Translation

Author

Vaswani, Ashish, Bengio, Samy, Brevdo, Eugene, Chollet, Francois, Gomez, Aidan N., Gouws, Stephan, Jones, Llion, Kaiser, Łukasz, Kalchbrenner, Nal, Parmar, Niki, Sepassi, Ryan, Shazeer, Noam, and Uszkoreit, Jakob

Subjects

FOS: Computer and information sciences, Computer Science - Learning, Computer Science - Computation and Language, Statistics - Machine Learning, Machine Learning (stat.ML), Computation and Language (cs.CL), Machine Learning (cs.LG)

Abstract

Tensor2Tensor is a library for deep learning models that is well-suited for neural machine translation and includes the reference implementation of the state-of-the-art Transformer model., Comment: arXiv admin note: text overlap with arXiv:1706.03762

Published

2018

4. Mesh-TensorFlow: Deep Learning for Supercomputers

Author

Shazeer, Noam, Cheng, Youlong, Parmar, Niki, Tran, Dustin, Vaswani, Ashish, Koanantakool, Penporn, Hawkins, Peter, Lee, HyoukJoong, Hong, Mingsheng, Young, Cliff, Sepassi, Ryan, and Hechtman, Blake

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Computer Science - Distributed, Parallel, and Cluster Computing, Statistics - Machine Learning, Machine Learning (stat.ML), Distributed, Parallel, and Cluster Computing (cs.DC), Machine Learning (cs.LG)

Abstract

Batch-splitting (data-parallelism) is the dominant distributed Deep Neural Network (DNN) training strategy, due to its universal applicability and its amenability to Single-Program-Multiple-Data (SPMD) programming. However, batch-splitting suffers from problems including the inability to train very large models (due to memory constraints), high latency, and inefficiency at small batch sizes. All of these can be solved by more general distribution strategies (model-parallelism). Unfortunately, efficient model-parallel algorithms tend to be complicated to discover, describe, and to implement, particularly on large clusters. We introduce Mesh-TensorFlow, a language for specifying a general class of distributed tensor computations. Where data-parallelism can be viewed as splitting tensors and operations along the "batch" dimension, in Mesh-TensorFlow, the user can specify any tensor-dimensions to be split across any dimensions of a multi-dimensional mesh of processors. A Mesh-TensorFlow graph compiles into a SPMD program consisting of parallel operations coupled with collective communication primitives such as Allreduce. We use Mesh-TensorFlow to implement an efficient data-parallel, model-parallel version of the Transformer sequence-to-sequence model. Using TPU meshes of up to 512 cores, we train Transformer models with up to 5 billion parameters, surpassing state of the art results on WMT'14 English-to-French translation task and the one-billion-word language modeling benchmark. Mesh-Tensorflow is available at https://github.com/tensorflow/mesh .

Published

2018