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The Laplacian in RL: Learning Representations with Efficient Approximations

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arxiv 1810.04586 v1 pith:HYU5RMMV submitted 2018-10-10 cs.LG stat.ML

The Laplacian in RL: Learning Representations with Efficient Approximations

classification cs.LG stat.ML
keywords laplacianeigenvectorsfinite-stategraphlearningrepresentationsettingstabular
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The smallest eigenvectors of the graph Laplacian are well-known to provide a succinct representation of the geometry of a weighted graph. In reinforcement learning (RL), where the weighted graph may be interpreted as the state transition process induced by a behavior policy acting on the environment, approximating the eigenvectors of the Laplacian provides a promising approach to state representation learning. However, existing methods for performing this approximation are ill-suited in general RL settings for two main reasons: First, they are computationally expensive, often requiring operations on large matrices. Second, these methods lack adequate justification beyond simple, tabular, finite-state settings. In this paper, we present a fully general and scalable method for approximating the eigenvectors of the Laplacian in a model-free RL context. We systematically evaluate our approach and empirically show that it generalizes beyond the tabular, finite-state setting. Even in tabular, finite-state settings, its ability to approximate the eigenvectors outperforms previous proposals. Finally, we show the potential benefits of using a Laplacian representation learned using our method in goal-achieving RL tasks, providing evidence that our technique can be used to significantly improve the performance of an RL agent.

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Cited by 4 Pith papers

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