Damped harmonic oscillator revisited: a new approach to energy decay in the case of Coulomb, Stokes, and Newton damping

TL;DR

This paper introduces a new analytical approach to model energy decay in damped harmonic oscillators with Coulomb, Stokes, and Newton damping, providing accurate approximations and exact solutions, suitable for educational purposes.

Contribution

It presents a novel analytical framework that simplifies energy decay analysis in various damping scenarios without relying on amplitude equations.

Findings

Accurate approximate formulas for energy decay across damping types.

Exact solution derivation for Stokes damping without second-order differential equations.

Methodology validated against simulations and exact solutions.

Abstract

Approximate formulas are derived to describe energy loss in a harmonic oscillator that experiences three distinct damping mechanisms: constant-magnitude (Coulomb), velocity-proportional (Stokes), and velocity-squared (Newton), using fundamental mathematical methods and physical insight. Our methodology leverages an understanding of the free harmonic oscillator and the inherent link between energy dissipation rates and the power exerted by damping forces. We establish a direct analytical framework for assessing the energy of a damped harmonic oscillator, obviating the need for amplitude-based equations. The simplicity of our findings is accompanied by their remarkable accuracy when validated against exact or computational simulations. In addition to an excellent approximate description of the energy decay, we also show how to derive an exact solution in the case of Stokes damping without relying on the standard procedure for solving second-order differential equations. The theoretical underpinnings and mathematical strategies employed are well-suited for undergraduate-level or advanced high school physics instruction.