具有树状机械结构的蛇形游动机器人的递归逆动力学

2023 IEEE International Conference on Advanced Robotics and Its Social Impacts (ARSO) Pub Date : 2023-06-05 DOI:10.1109/ARSO56563.2023.10187577

Xiaowei Xie, J. Herault, V. Lebastard, F. Boyer

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引用次数: 0

摘要

本文报道了一种新型蛇形机器人NATRIX的递归逆动力学模型。这个机器人的设计目的是保持它对水面的注视，并监测敏感的生态系统。该机器人的灵感来自真实的蛇，其特点是旋转外壳，允许改变每个模块的浸入程度，并迅速重新稳定机器人。这种新的自由度导致了原始的树状几何结构。我们在这里提出了理论模型和数值解，使我们能够实时模拟机器人在水面上的动力学。在报告了模拟器的基准之后，我们提出了令人惊讶的初步结果，表明在给定频率范围内倾覆的可能性。

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Recursive inverse dynamics of a swimming snake-like robot with a tree-like mechanical structure

In this paper, we report a recursive inverse dynamical model for a new snake-like robot called NATRIX. This robot has been designed to maintain its gaze on the water surface and monitor sensible ecosystems. Inspired by real snakes, the robot features rotating outer shells allowing to change the level of immersion of each module and re-stabilize quickly the robot. This new degree of freedom leads to an original tree-like geometric structure. We present here the theoretical model and the numerical solutions that allow us to simulate in real time the dynamics of the robot on the water surface. After reporting the benchmark of the simulator, we present surprising preliminary results suggesting the possibility of capsizing for a given frequency range.

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2023 IEEE International Conference on Advanced Robotics and Its Social Impacts (ARSO)

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