Abstract
Current maintenance intervals of mechanical systems are scheduled a priori based on the life of the system, resulting in expensive maintenance scheduling, and often undermining the safety of passengers. Going forward, the actual usage of a vehicle will be used to predict stresses in its structure, and therefore, to define a specific maintenance scheduling. Machine learning (ML) algorithms can be used to map a reduced set of data coming from real-time measurements of a structure into a detailed/high-fidelity finite element analysis (FEA) model of the same system. As a result, the FEA-based ML approach will directly estimate the stress distribution over the entire system during operations, thus improving the ability to define ad-hoc, safe, and efficient maintenance procedures. The paper initially presents a review of the current state-of-the-art of ML methods applied to finite elements. A surrogate finite element approach based on ML algorithms is also proposed to estimate the time-varying response of a one-dimensional beam. Several ML regression models, such as decision trees and artificial neural networks, have been developed, and their performance is compared for direct estimation of the stress distribution over a beam structure. The surrogate finite element models based on ML algorithms are able to estimate the response of the beam accurately, with artificial neural networks providing more accurate results.
Highlights
Structural health monitoring (SHM) aims at accurately identifying the current state and the behavior of a structure by analyzing data collected through various monitoring devices and sensors over the structure [1,2,3]
This section describes the results from XGBoost, Random forest (RF), and artificial neural networks (ANN) and evaluates their performance as a surrogate for an finite element analysis (FEA) in the one-dimensional mechanical systems used in this study
The results suggest that machine learning (ML) models developed for predicting the acceleration in the beam are promising, with ANNs as the most predictive model among the three
Summary
Structural health monitoring (SHM) aims at accurately identifying the current state and the behavior of a structure by analyzing data collected through various monitoring devices and sensors over the structure [1,2,3]. Stress analysis is a pivotal part of any mechanical system design. A finite element analysis (FEA) is generally used to perform stress analysis of complex structures and systems for design, maintenance, and safety evaluation across many industries, such as aerospace, automotive, architecture, and biomedical engineering [4,5,6,7]. A review of literature, presented in Section 2 of this work, describes preliminary attempts to use machine learning (ML) algorithms in conjunction with finite element analyses, mostly to approach static biomechanical systems. The evaluation of the performance of regression ML algorithms in real-time estimation and prediction of stresses in time-varying mechanical systems is a rarely addressed area of research. This study aims to apply, validate and compare the performance of ML methods in accurate estimation of time-varying stresses as a surrogate for an FEA in a one-dimensional framework (beam structure)
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