Combined two-level damage identification strategy using ultrasonic guided waves and physical knowledge assisted machine learning

Data-driven analysis for damage assessment has a large potential in structural health monitoring (SHM) systems, where sensors are permanently attached to the structure, enabling continuous and frequent measurements. In this contribution, we propose a machine learning (ML) approach for automated damage detection, based on an ML toolbox for industrial condition monitoring. The toolbox combines multiple complementary algorithms for feature extraction and selection and automatically chooses the best combination of methods for the dataset at hand. Here, this toolbox is applied to a guided wave-based SHM dataset for varying temperatures and damage locations, which is freely available on the Open Guided Waves platform. A classification rate of 96.2% is achieved, demonstrating reliable and automated damage detection. Moreover, the ability of the ML model to identify a damaged structure at untrained damage locations and temperatures is demonstrated.

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A novel machine-learning approach for structural state identification using ultrasonic guided waves

Safety, Reliability, Risk and Life-Cycle Performance of Structures and Infrastructures ◽

10.1201/b16387-48 ◽

2014 ◽

pp. 321-328 ◽

Cited By ~ 6

Author(s):

S Roy ◽

F Chang ◽

S Lee ◽

P Pollock ◽

V Janapati

Keyword(s):

Machine Learning ◽

Structural State ◽

Guided Waves ◽

Ultrasonic Guided Waves ◽

Learning Approach ◽

State Identification ◽

Machine Learning Approach

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Improved Stress Estimation with Machine Learning and Ultrasonic Guided Waves

Experimental Mechanics ◽

10.1007/s11340-021-00787-6 ◽

2021 ◽

Author(s):

C. D. Villares Holguin ◽

H. V. Hultmann Ayala ◽

A. C. Kubrusly

Keyword(s):

Machine Learning ◽

Guided Waves ◽

Ultrasonic Guided Waves ◽

Stress Estimation

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Analysis of the Bath Motion in the MM-SQC Dynamics Using Unsupervised Machine Learning Dimensionality Reduction Approaches: Principal Component Analysis

10.26434/chemrxiv.13332530 ◽

2020 ◽

Author(s):

Jiawei Peng ◽

Yu Xie ◽

Deping Hu ◽

Zhenggang Lan

Keyword(s):

Machine Learning ◽

Principal Component Analysis ◽

Collective Motion ◽

Principal Component ◽

Component Analysis ◽

Nonadiabatic Dynamics ◽

Trajectory Data ◽

Unsupervised Machine Learning ◽

Physical Knowledge ◽

Vibronic Couplings

The system-plus-bath model is an important tool to understand nonadiabatic dynamics for large molecular systems. The understanding of the collective motion of a huge number of bath modes is essential to reveal their key roles in the overall dynamics. We apply the principal component analysis (PCA) to investigate the bath motion based on the massive data generated from the MM-SQC (symmetrical quasi-classical dynamics method based on the Meyer-Miller mapping Hamiltonian) nonadiabatic dynamics of the excited-state energy transfer dynamics of Frenkel-exciton model. The PCA method clearly clarifies that two types of bath modes, which either display the strong vibronic couplings or have the frequencies close to electronic transition, are very important to the nonadiabatic dynamics. These observations are fully consistent with the physical insights. This conclusion is obtained purely based on the PCA understanding of the trajectory data, without the large involvement of pre-defined physical knowledge. The results show that the PCA approach, one of the simplest unsupervised machine learning methods, is very powerful to analyze the complicated nonadiabatic dynamics in condensed phase involving many degrees of freedom.

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