A Lie group variational integrator in a closed-loop vector space without a multiplier

Mechanical Sciences Pub Date : 2024-03-12 DOI:10.5194/ms-15-169-2024

Long Bai, Lili Xia, Xinsheng Ge

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Abstract

Abstract. As a non-tree multi-body system, the dynamics model of four-bar mechanism is a differential algebraic equation. The constraints breach problem leads to many problems for computation accuracy and efficiency. With the traditional method, constructing an ODE-type dynamics equation for it is difficult or impossible. In this exploration, the dynamics model is built with geometry mechanic theory. The kinematic constraint variation relation of a closed-loop system is built in matrix and vector space with Lie group and Lie algebra theory respectively. The results indicate that the attitude variation between the driven body and the follower body has a linear recursion relation, which is the basis for dynamics modelling. With the Lie group variational integrator method, the closed-loop system Lagrangian dynamics model is built in vector space, with Legendre transformation. The dynamics model is reduced to be the Hamilton type. The kinematic model and dynamics model are solved using Newton iteration and the Runge–Kutta method respectively. As a special case of a crank and rocker mechanism, the dynamics character of a parallelogram mechanism is presented to verify the good structure conservation character of the closed-loop geometry dynamics model.

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无乘法器闭环矢量空间中的李群变积分器

摘要作为一个非树型多体系统，四杆机构的动力学模型是一个微分代数方程。约束条件突破问题导致了许多计算精度和效率问题。用传统方法很难或根本无法构建其 ODE 型动力学方程。在这一探索中，动力学模型是用几何力学理论建立的。利用李群理论和李代数理论分别在矩阵空间和矢量空间建立闭环系统的运动学约束变化关系。结果表明，从动体和从动体之间的姿态变化具有线性递归关系，这是动力学建模的基础。利用李群变分积分法，在矢量空间建立了闭环系统拉格朗日动力学模型，并进行了 Legendre 变换。动力学模型简化为汉密尔顿类型。运动模型和动力学模型分别采用牛顿迭代法和 Runge-Kutta 法求解。作为曲柄和摇杆机构的一个特例，介绍了平行四边形机构的动力学特性，以验证闭环几何动力学模型的良好结构守恒特性。

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Mechanical Sciences

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