The parametric spring-mass system, its connection with non-linear optics, and an approach for undergraduate students

TL;DR

This paper explores the complex dynamics of a spring-mass system, providing experimental and simulation insights, and draws an analogy with non-linear optics to enhance undergraduate physics education.

Contribution

It offers a systematic study of the parametric behavior of the spring-mass system and connects its nonlinear dynamics to non-linear optical phenomena, enriching teaching methods.

Findings

Experimental investigations reveal various motion waveforms during resonance.

The energy transfer between modes depends on frequency ratios and excitation strength.

An analogy with non-linear optical frequency conversion is established.

Abstract

The spring-mass system studied in undergraduate physics laboratories may exhibit complex dynamics due to the simultaneous action of gravitational and elastic forces in addition to air friction. In the first part of this paper, we describe a laboratory experiment aimed at beginner students which also gives those with a more advanced background an opportunity to explore more complex aspects of the motions involved. If students are not given predefined apparatus but are allowed instead to design their own set-up for the experiment, they may also learn something about the thought processes and experimental procedures used in physics. In the second part of this paper, we present a systematic study of the parametric behavior of the system because teachers have to master its dynamics. The non-linear interaction between the vertical and the pendular oscillations in a vertical spring-mass system depends on the ratio between the frequencies of the two motions and on the motion's excitation. Systematic experimental investigations, coupled with relevant simulations, highlight the many aspects of physics involved in the partition of energy transfer between the two modes. The different motion waveforms obtained by sweeping through the resonance curve and by applying small and strong excitations are presented and analyzed. The influence of the unavoidable spurious motions is investigated. An analogy between the parametric interaction in a spring--mass system and that found during frequency conversion in non-linear optical crystals is discussed.