Deep Reinforcement Learning Control of an Autonomous Wheeled Robot in a Challenge Task: Combined Visual and Dynamics Sensoring

2019 19th International Conference on Advanced Robotics (ICAR) Pub Date : 2019-12-01 DOI:10.1109/ICAR46387.2019.8981598

Luiz Afonso Marão, Larissa Casteluci, Ricardo V. Godoy, Henrique B. Garcia, D. V. Magalhães, G. Caurin

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Abstract

This paper presents a Deep Reinforcement Learning agent for a 4-wheeled rover in a multi-goal competition task, under the influence of noisy GPS measurements. A previous related work has implemented a similar agent to the same task using only the raw dynamics measurements as observations. The Proximal Policy Optimization algorithm combined to Universal Value Function Approximators resulted in a system able to successfully overcome very noisy GPS observations and complete the challenge task. This work introduced a frontal camera to add visual input to the rover observations during the task execution. The main change on the algorithm is on the neural networks' architectures, in which a second input layer was added to deal with the image observations. In a few alternate versions of the networks, Long Short-Term Memory (LSTM) cells were included in the architecture as well. The addition of the camera did not present a significant increase in stability or performance of the network, and the computation time require increased.

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挑战任务中自主轮式机器人的深度强化学习控制:结合视觉和动态传感

针对GPS测量噪声影响下的四轮漫游车多目标竞争任务，提出了一种深度强化学习智能体。先前的相关工作已经实现了一个类似的代理，仅使用原始动态测量作为观察。将近端策略优化算法与通用值函数逼近器相结合，使系统能够成功克服非常嘈杂的GPS观测并完成挑战任务。这项工作引入了一个正面摄像头，在任务执行期间为漫游者的观测增加视觉输入。该算法的主要变化是在神经网络的架构上，其中增加了第二个输入层来处理图像观测。在一些替代版本的网络中，长短期记忆(LSTM)单元也包含在体系结构中。摄像机的加入并没有显著提高网络的稳定性或性能，而且需要的计算时间增加了。

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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2019 19th International Conference on Advanced Robotics (ICAR)

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