Hydrodynamic modeling of pectoral fin having varying thickness for biomimetic fish robot

2017 7th IEEE International Conference on System Engineering and Technology (ICSET) Pub Date : 2017-10-01 DOI:10.1109/ICSENGT.2017.8123426

Van Anh Pham, T. Nguyen, T. Vo

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Abstract

Pectoral fin types of biological fish have an enormous diversity, and they play an essential role in locomotion of fish. The adaptation to shapes and movement mechanism of pectoral fin types helps swimming motion of the main body effectively, that results in the high flexibility and maneuverability of locomotion. This paper proposes a hydrodynamic model of a type of flexible pectoral fin (FPF), which can be used to increase the robotic fish motion efficient and reduce the consumed energy. The pectoral fin has the symmetrical shape and varying thickness along the symmetrical axis. Based on the Lagrange energetic method, Assumed Mode Method (AMM), and Rayleigh-Ritz method, the mathematical model of deformation and estimated thrust of the pectoral fin is described explicitly. The effect of inertia and damping factors are modeled by the Morison force. The numerical simulations and some initial experiments are demonstrated to verify the agreement of theoretical and empirical model. The proposed model is expected to support in issues of modeling whole of robotic fish and control design effectively.

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仿生鱼类机器人变厚度胸鳍的水动力学建模

生物鱼类的胸鳍种类繁多，在鱼类运动中起着至关重要的作用。胸鳍类型对形状和运动机制的适应，有效地帮助了主体的游泳运动，从而使运动具有很高的灵活性和机动性。本文提出了一种柔性胸鳍(FPF)的水动力学模型，该模型可用于提高机器鱼的运动效率和降低能量消耗。胸鳍形状对称，沿对称轴厚度变化。基于拉格朗日能量法、假设模态法(AMM)和瑞利-里兹法，明确地描述了胸鳍变形和估计推力的数学模型。惯量和阻尼因素的影响用莫里森力来模拟。通过数值模拟和初步实验，验证了理论模型与经验模型的一致性。该模型可为机器鱼的整体建模和控制设计提供有效的支持。

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2017 7th IEEE International Conference on System Engineering and Technology (ICSET)

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