Generalization of the Concept of Bandwidth

TL;DR

This paper proposes a generalized, energy-based definition of bandwidth for oscillatory systems, applicable to linear and nonlinear, time-varying and invariant systems, overcoming limitations of traditional methods.

Contribution

It introduces a root mean square bandwidth concept linked to energy dissipation, applicable across diverse oscillatory systems, including nonlinear and time-varying cases.

Findings

Traditional half-power bandwidth has limitations in nonlinear systems.

The new energy-based bandwidth aligns with nonlinear dynamics.

Applications demonstrate improved accuracy in nonlinear oscillators.

Abstract

In the sciences and engineering, the concept of bandwidth is often subject to interpretation depending upon context and the requirements of a specific community. The focus of this work is to formulate this concept for a general class of passive oscillatory dynamical systems, including but not limited to mechanical, structural, acoustic, electrical, and optical. Typically, the bandwidth of these systems is determined by the half-power (-3 dB) method, and the result is often referred to as half-power bandwidth. The fundamental assumption underlying this definition is that the system performance degrades once its power decreases by 50%; moreover, there are restrictive conditions that are rarely met. Here the concept of root mean square bandwidth is considered, justified by the Fourier uncertainty principle, to generalize the definition of bandwidth to encompass linear and nonlinear, single and multi-mode, low and high loss and time-varying and invariant oscillating systems. By tying the bandwidth of an oscillatory dynamical system directly to its dissipative capacity, one can formulate a definition based solely on its transient energy evolution, effectively circumventing the previous restrictions. Further, applications are given that highlight the limitations of the traditional half-power bandwidth; including a Duffing oscillator with hardening nonlinearity, and a geometrically nonlinear oscillator with tunable hardening or softening nonlinearity. The resulting energy-dependent bandwidth computations are compatible with the nonlinear dynamics of these systems, since at low energies they recover the half-power bandwidth, whereas at high energies they accurately capture the nonlinear physics. Moreover, the bandwidth computation is directly tied to nonlinear harmonic generation in the transient dynamics.