Experimental identification of multimode traveling waves in a coupled wave-tube

TL;DR

This paper develops and tests methods for decomposing multimode traveling waves in waveguides, enabling better analysis and control of wave propagation in nondestructive testing applications.

Contribution

It introduces new schemes for multimode wave decomposition and demonstrates their effectiveness through experimental validation on an acoustic wave tube.

Findings

Including additional propagating modes improves analysis accuracy.

Recursive multichannel LMS method enables fast wave decomposition.

Methods facilitate control of wave propagation patterns.

Abstract

An essential part of nondestructive testing and experimental modeling of waveguides is the decomposition of propagating wave patterns. The traveling wave ratio is a measure of partial reflections assisting in quantifying the pureness of a single traveling wave from a power flow perspective. This paper expands the notion of traveling wave ratio for multimode systems and outlines several schemes capable of decomposing the waves into their different traveling modes while quantifying their traveling and standing proportions individually. A method to strike an optimal balance between increasing model order and to maintain low uncertainty is proposed. An experimental study performed on an acoustic wave tube, which utilizes the various methods while assessing their accuracy and performance, is reported. The results described here emphasize the importance of including additional propagating modes. In addition, the results illustrate the capability of using the recursive multichannel least-mean-squares method for both a fast decomposition and as a basis to formulate closed-loop schemes controlling the wave's propagation patterns.