Stochastic Identification of Guided Wave Propagation under Ambient Temperature via Non-Stationary Time Series Models

In the context of active-sensing guided-wave-based acousto-ultrasound structural health monitoring, environmental and operational variability poses a considerable challenge in the damage diagnosis process as they may mask the presence of damage. In this work, the stochastic nature of guided wave propagation due to the small temperature variation, naturally occurring in the ambient or environment, is rigorously investigated and modeled with the help of stochastic time-varying time series models, for the first time, with a system identification point of view. More specifically, the output-only recursive maximum likelihood time-varying auto-regressive model (RML-TAR) is employed to investigate the uncertainty in guided wave propagation by analyzing the time-varying model parameters. The steps and facets of the identification procedure are presented, and the obtained model is used for modeling the uncertainty of the time-varying model parameters that capture the underlying dynamics of the guided waves. The stochasticity inherent in the modal properties of the system, such as natural frequencies and damping ratios, is also analyzed with the help of the identified RML-TAR model. It is stressed that the narrow-band high-frequency actuation for guided wave propagation excites more than one frequency in the system. The values and the time evolution of those frequencies are analyzed, and the associated uncertainties are also investigated. In addition, a high-fidelity finite element (FE) model was established and Monte Carlo simulations on that FE model were carried out to understand the effect of small temperature perturbation on guided wave signals.

Automated summary

This study rigorously investigates and models the stochastic nature of guided wave propagation in the context of active-sensing guided-wave-based acousto-ultrasound structural health monitoring. The identified RML-TAR model is used to analyze the uncertainty in guided wave propagation, including time-varying model parameters and modal properties such as natural frequencies and damping ratios. Additionally, Monte Carlo simulations on a high-fidelity finite element model are conducted to understand the effect of small temperature perturbation on guided wave signals.