Matteo Hessel scite author profile

The reinforcement learning community has made great strides in designing algorithms capable of exceeding human performance on specific tasks. These algorithms are mostly trained one task at the time, each new task requiring to train a brand new agent instance. This means the learning algorithm is general, but each solution is not; each agent can only solve the one task it was trained on. In this work, we study the problem of learning to master not one but multiple sequentialdecision tasks at once. A general issue in multi-task learning is that a balance must be found between the needs of multiple tasks competing for the limited resources of a single learning system. Many learning algorithms can get distracted by certain tasks in the set of tasks to solve. Such tasks appear more salient to the learning process, for instance because of the density or magnitude of the in-task rewards. This causes the algorithm to focus on those salient tasks at the expense of generality. We propose to automatically adapt the contribution of each task to the agent's updates, so that all tasks have a similar impact on the learning dynamics. This resulted in state of the art performance on learning to play all games in a set of 57 diverse Atari games. Excitingly, our method learned a single trained policy -with a single set of weights -that exceeds median human performance. To our knowledge, this was the first time a single agent surpassed human-level performance on this multi-task domain. The same approach also demonstrated state of the art performance on a set of 30 tasks in the 3D reinforcement learning platform DeepMind Lab.

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Dueling Network Architectures for Deep Reinforcement Learning

Wang

Schaul

Hessel

et al. 2015

Preprint

231

293

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Rainbow: Combining Improvements in Deep Reinforcement Learning

Hessel

Modayil

Hasselt

et al. 2018

AAAI

925

275

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The deep reinforcement learning community has made several independent improvements to the DQN algorithm. However, it is unclear which of these extensions are complementary and can be fruitfully combined. This paper examines six extensions to the DQN algorithm and empirically studies their combination. Our experiments show that the combination provides state-of-the-art performance on the Atari 2600 benchmark, both in terms of data efficiency and final performance. We also provide results from a detailed ablation study that shows the contribution of each component to overall performance.

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Rainbow: Combining Improvements in Deep Reinforcement Learning

Hessel¹,

Modayil²,

Hasselt³

et al. 2017

Preprint

146

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Matteo Hessel

Multi-Task Deep Reinforcement Learning with PopArt

Dueling Network Architectures for Deep Reinforcement Learning

Rainbow: Combining Improvements in Deep Reinforcement Learning

Rainbow: Combining Improvements in Deep Reinforcement Learning

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