A Projection-Based Derivation of the Equations of Motion for the Moving Frame Method for Multi-Body Dynamics

Volume 9: Engineering Education Pub Date : 2021-11-01 DOI:10.1115/imece2021-72324

D. M. Luchtenburg, Mili Shah, T. Impelluso, Thorstein Ravneberg Rykkje

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Abstract

The moving frame method for multi-body dynamics, established by Murakami in [10] and [11], embodies a consistent notation and mathematical framework that simplifies the derivation of equations of motion of complex systems. The derivation of the equations of motion follows Hamilton’s principle and requires the calculation of virtual angular velocities and the corresponding virtual rotational displacements. The goal of this paper is to present a projection-based approach, which only requires knowledge of Euler’s first and second law, that results in the same equation of motion. The constraints need not satisfy d’Alembert’s principle and the projection is based on a generalization of Gauss’ principle of least constraint [14]. One advantage of the proposed method is that it avoids variational principles and therefore is more accessible to undergraduate students. In addition, the final form of the equation of motion is more easily understood. We motivate our approach using the example of the simple pendulum, derive the main result, and apply the methodology for derivation of the equations of motion for a modified Chaplygin sleigh and a rotary pendulum.

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多体动力学运动框架法运动方程的投影推导

Murakami在[10]和[11]中建立的多体动力学的运动框架方法，体现了一种统一的符号和数学框架，简化了复杂系统运动方程的推导。运动方程的推导遵循汉密尔顿原理，需要计算虚角速度和相应的虚旋转位移。本文的目标是提出一种基于投影的方法，它只需要欧拉第一定律和第二定律的知识，就可以得到相同的运动方程。约束不需要满足达朗贝尔原理，投影是基于高斯最小约束原理的推广[14]。所提出的方法的一个优点是它避免了变分原理，因此对本科生来说更容易理解。此外，运动方程的最终形式更容易理解。我们使用单摆的例子来激励我们的方法，推导出主要结果，并应用该方法推导出改进的Chaplygin雪橇和旋转摆的运动方程。

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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Volume 9: Engineering Education

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