用强化学习衰减机器人导航控制器的随机性

James Gillespie, I. Rañó, N. Siddique, Jose A. Santos, M. Khamassi
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引用次数: 0

摘要

britenberg车辆是基于传感器的轮式机器人局部导航的仿生控制器,已在多个现实世界的机器人实现中使用。实现这种非线性控制机制的常见方法是通过神经网络将传感与运动动作连接起来,但调整权重以获得适当的闭环导航行为可能非常具有挑战性。标准方法使用手动调谐尖峰或循环神经网络,或使用进化方法学习前馈网络的权重。最近,在无噪声传感器的假设下,强化学习被用于模拟britenberg车辆3a(一种仿生轮式机器人目标搜索模型)的神经控制器学习。然而,真实的传感器受到不同程度的噪音的影响,多项研究表明,Braitenberg车辆甚至可以在户外机器人上工作,这表明这些控制机制在恶劣的动态环境中也能工作。本文表明,在传感器噪声起不可忽略作用的情况下,可以使用策略梯度强化学习来学习Braitenberg车辆3a的鲁棒神经控制器。学习到的控制器具有鲁棒性,并试图减弱噪声对模拟随机车辆闭环导航行为的影响。我们将使用强化学习学习的神经控制器与简单的手动调谐控制器进行比较,并展示神经控制机制如何优于naïve控制器。结果通过闭环随机系统的计算机模拟加以说明。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Using Reinforcement Learning to Attenuate for Stochasticity in Robot Navigation Controllers
Braitenberg vehicles are bio-inspired controllers for sensor-based local navigation of wheeled robots that have been used in multiple real world robotic implementations. The common approach to implement such non-linear control mechanisms is through neural networks connecting sensing to motor action, yet tuning the weights to obtain appropriate closed-loop navigation behaviours can be very challenging. Standard approaches used hand tuned spiking or recurrent neural networks, or learnt the weights of feedforward networks using evolutionary approaches. Recently, Reinforcement Learning has been used to learn neural controllers for simulated Braitenberg vehicle 3a – a bio-inspired model of target seeking for wheeled robots – under the assumption of noiseless sensors. Real sensors, however, are subject to different levels of noise, and multiple works have shown that Braitenberg vehicles work even on outdoor robots, demonstrating that these control mechanisms work in harsh and dynamic environments. This paper shows that a robust neural controller for Braitenberg vehicle 3a can be learnt using policy gradient reinforcement learning in scenarios where sensor noise plays a non negligible role. The learnt controller is robust and tries to attenuate the effects of noise in the closed- loop navigation behaviour of the simulated stochastic vehicle. We compare the neural controller learnt using Reinforcement Learning with a simple hand tuned controller and show how the neural control mechanism outperforms a naïve controller. Results are illustrated through computer simulations of the closed-loop stochastic system.
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