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An FPGA-Based On-Device Reinforcement Learning Approach using Online Sequential Learning

Machine Learning 2023-03-14 v4 Machine Learning

Abstract

DQN (Deep Q-Network) is a method to perform Q-learning for reinforcement learning using deep neural networks. DQNs require a large buffer and batch processing for an experience replay and rely on a backpropagation based iterative optimization, making them difficult to be implemented on resource-limited edge devices. In this paper, we propose a lightweight on-device reinforcement learning approach for low-cost FPGA devices. It exploits a recently proposed neural-network based on-device learning approach that does not rely on the backpropagation method but uses OS-ELM (Online Sequential Extreme Learning Machine) based training algorithm. In addition, we propose a combination of L2 regularization and spectral normalization for the on-device reinforcement learning so that output values of the neural network can be fit into a certain range and the reinforcement learning becomes stable. The proposed reinforcement learning approach is designed for PYNQ-Z1 board as a low-cost FPGA platform. The evaluation results using OpenAI Gym demonstrate that the proposed algorithm and its FPGA implementation complete a CartPole-v0 task 29.77x and 89.40x faster than a conventional DQN-based approach when the number of hidden-layer nodes is 64.

Keywords

Cite

@article{arxiv.2005.04646,
  title  = {An FPGA-Based On-Device Reinforcement Learning Approach using Online Sequential Learning},
  author = {Hirohisa Watanabe and Mineto Tsukada and Hiroki Matsutani},
  journal= {arXiv preprint arXiv:2005.04646},
  year   = {2023}
}

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