Exact Solutions of Nonlinear Second-Order Autonomous Ordinary Differential Equations: Application to Mechanical Systems

Dynamics (Pembroke, Ont.) Pub Date : 2023-08-14 DOI:10.3390/dynamics3030024

Murillo V. B. Santana

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Abstract

Many physical processes can be described via nonlinear second-order ordinary differential equations and so, exact solutions to these equations are of interest as, aside from their accuracy, they may reveal beforehand key properties of the system’s response. This work presents a method for computing exact solutions of second-order nonlinear autonomous undamped ordinary differential equations. The solutions are divided into nine cases, each depending on the initial conditions and the system’s first integral. The exact solutions are constructed via a suitable parametrization of the unknown function into a class of functions capable of representing its behavior. The solution is shown to exist and be well-defined in all cases for a general nonlinear form of the differential equation. Practical properties of the solution, such as its period, time to reach an extreme value or long-term behavior, are obtained without the need of computing the solution in advance. Illustrative examples considering different types of nonlinearity present in classical physical systems are used to further validate the obtained exact solutions.

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非线性二阶自治常微分方程的精确解:在机械系统中的应用

许多物理过程可以通过非线性二阶常微分方程来描述，因此，这些方程的精确解是有趣的，因为除了它们的准确性之外，它们可以预先揭示系统响应的关键属性。本文提出了一种二阶非线性自治无阻尼常微分方程精确解的计算方法。解分为九种情况，每种情况取决于初始条件和系统的第一个积分。通过对未知函数进行适当的参数化，构造出精确的解，使其成为能够表示其行为的一类函数。对于一般非线性形式的微分方程，证明了在所有情况下解的存在性和良好的定义性。解的实际性质，如周期、达到极值的时间或长期行为，无需事先计算解即可获得。通过考虑经典物理系统中不同类型非线性的实例，进一步验证了所得到的精确解。

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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Dynamics (Pembroke, Ont.)

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