Reinforcement learning for non-prehensile manipulation: Transfer from simulation to physical system

2018 IEEE International Conference on Simulation, Modeling, and Programming for Autonomous Robots (SIMPAR) Pub Date : 2018-03-28 DOI:10.1109/SIMPAR.2018.8376268

Kendall Lowrey, S. Kolev, Jeremy Dao, A. Rajeswaran, E. Todorov

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引用次数: 52

Abstract

Reinforcement learning has emerged as a promising methodology for training robot controllers. However, most results have been limited to simulation due to the need for a large number of samples and the lack of automated-yet-safe data collection methods. Model-based reinforcement learning methods provide an avenue to circumvent these challenges, but the traditional concern has been the mismatch between the simulator and the real world. Here, we show that control policies learned in simulation can successfully transfer to a physical system, composed of three Phantom robots pushing an object to various desired target positions. We use a modified form of the natural policy gradient algorithm for learning, applied to a carefully identified simulation model. The resulting policies, trained entirely in simulation, work well on the physical system without additional training. In addition, we show that training with an ensemble of models makes the learned policies more robust to modeling errors, thus compensating for difficulties in system identification. The results are illustrated in the accompanying video.

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非握握性操作的强化学习:从模拟到物理系统的转移

强化学习已经成为一种很有前途的训练机器人控制器的方法。然而，由于需要大量的样本和缺乏自动化但安全的数据收集方法，大多数结果仅限于模拟。基于模型的强化学习方法提供了规避这些挑战的途径，但传统的关注点是模拟器与现实世界之间的不匹配。在这里，我们展示了在仿真中学习到的控制策略可以成功地转移到一个物理系统中，该系统由三个幻影机器人组成，将物体推到各种期望的目标位置。我们使用自然策略梯度算法的改进形式进行学习，应用于仔细识别的模拟模型。由此产生的策略，完全在模拟中训练，在物理系统上运行良好，无需额外的训练。此外，我们表明，使用模型集合进行训练使学习到的策略对建模错误更具鲁棒性，从而补偿了系统识别中的困难。结果在附带的视频中说明。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2018 IEEE International Conference on Simulation, Modeling, and Programming for Autonomous Robots (SIMPAR)

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