Deep reinforcement learning for real-world quadrupedal locomotion: a comprehensive review

Intelligence & Robotics Pub Date : 1900-01-01 DOI:10.20517/ir.2022.20

Hongyin Zhang, Li He, Donglin Wang

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引用次数: 2

Abstract

Building controllers for legged robots with agility and intelligence has been one of the typical challenges in the pursuit of artificial intelligence (AI). As an important part of the AI field, deep reinforcement learning (DRL) can realize sequential decision making without physical modeling through end-to-end learning and has achieved a series of major breakthroughs in quadrupedal locomotion research. In this review article, we systematically organize and summarize relevant important literature, covering DRL algorithms from problem setting to advanced learning methods. These algorithms alleviate the specific problems encountered in the practical application of robots to a certain extent. We first elaborate on the general development trend in this field from several aspects, such as the DRL algorithms, simulation environments, and hardware platforms. Moreover, core components in the algorithm design, such as state and action spaces, reward functions, and solutions to reality gap problems, are highlighted and summarized. We further discuss open problems and propose promising future research directions to discover new areas of research.

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现实世界四足运动的深度强化学习:全面回顾

为具有敏捷性和智能的有腿机器人构建控制器一直是追求人工智能(AI)的典型挑战之一。深度强化学习(deep reinforcement learning, DRL)作为人工智能领域的重要组成部分，通过端到端学习可以实现不需要物理建模的顺序决策，并在四足运动研究中取得了一系列重大突破。在这篇综述文章中，我们系统地组织和总结了相关的重要文献，涵盖了从问题设置到高级学习方法的DRL算法。这些算法在一定程度上缓解了机器人实际应用中遇到的具体问题。本文首先从DRL算法、仿真环境、硬件平台等几个方面阐述了该领域的总体发展趋势。重点总结了算法设计中的核心组件，如状态与动作空间、奖励函数、现实差距问题的解决方案等。我们进一步讨论开放的问题，并提出有希望的未来研究方向，以发现新的研究领域。

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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Intelligence & Robotics

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