Adaptive neural oscillators with synaptic plasticity for locomotion control of a snake-like robot with screw-drive mechanism

2013 IEEE International Conference on Robotics and Automation Pub Date : 2013-05-06 DOI:10.1109/ICRA.2013.6631050

Timo Nachstedt, F. Wörgötter, P. Manoonpong, Ryo Ariizumi, Yuichi Ambe, F. Matsuno

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引用次数: 13

Abstract

Central pattern generators (CPGs) play a crucial role for animal locomotion control. They can be entrained by sensory feedback to induce proper rhythmic patterns and even store the entrained patterns through connection weights. Inspired by this biological finding, we use four adaptive neural oscillators with synaptic plasticity as CPGs for locomotion control of our real snake-like robot with screw-drive mechanism. Each oscillator consists of only three neurons and uses adaptive mechanisms based on frequency adaptation and Hebbian-type learning rules. It autonomously generates proper periodic patterns for the robot locomotion and can be entrained by sensory feedback to memorize the patterns. The adaptive CPG system in conjunction with a simple control strategy enables the robot to perform self-tuning behavior which is robust against short-time perturbations. The generated behavior is also energy efficient. In addition, the robot can also cope with corners as well as move through a complex environment with obstacles.

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具有突触可塑性的自适应神经振荡器用于螺旋驱动蛇形机器人的运动控制

中枢模式发生器(CPGs)在动物运动控制中起着至关重要的作用。它们可以被感官反馈诱导出适当的节奏模式，甚至可以通过连接权重存储所携带的模式。受这一生物学发现的启发，我们使用4个具有突触可塑性的自适应神经振荡器作为cpg来控制我们的螺旋驱动的真实蛇形机器人的运动。每个振荡器仅由三个神经元组成，并使用基于频率自适应和hebbian型学习规则的自适应机制。它可以自动生成适合机器人运动的周期模式，并可以通过感官反馈来记忆这些模式。自适应CPG系统与简单的控制策略相结合，使机器人能够执行自调谐行为，这对短时扰动具有鲁棒性。生成的行为也是节能的。此外，该机器人还可以处理拐角，以及在有障碍物的复杂环境中移动。

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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2013 IEEE International Conference on Robotics and Automation

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