Abstract
The demand for efficient and accurate finite element analysis (FEA) is becoming more prevalent with the increase in advanced calibration technologies and sensor-based monitoring methods. The current research explores a deep learning-based methodology to calibrate FEA results. The utilization of monitoring reference results from measurements, e.g., terrestrial laser scanning, can help to capture the actual features in the static loading process. We learn the deviation sequence results between the standard FEA computations with the simplified geometry and refined reference values by the long short-term memory method. The complex changing principles in different deviations are trained and captured effectively in the training process of deep learning. Hence, we generate the FEA sequence results corresponding to next adjacent loading steps. The final FEA computations are calibrated by the threshold control. The calibration reduces the mean square errors of the FEA future sequence results significantly. This strengthens the calibration depth. Consequently, the calibration of FEA computations with deep learning can play a helpful role in the prediction and monitoring problems regarding the future structural behaviors.
Highlights
The field of artificial intelligence has been developing rapidly in recent years [1]
This paper focuses on the finite element analysis (FEA) calibration to further improve its efficiency, depth, and accuracy by utilizing the advanced deep learning approach
One of the final aims of this research is to provide fast calibrated image sequence results of FEA behavior computations using the benefit of the prediction technology regarding future images
Summary
The field of artificial intelligence has been developing rapidly in recent years [1]. It has made significant contributions regarding the optimization and prediction of many problems [1,2,3]. The machine learning-based approach has proved to be a suitable method to solve the finite element analysis (FEA) calibration problem [4]. Its accuracy and calibration depth still need to be improved significantly. This paper focuses on the FEA calibration to further improve its efficiency, depth, and accuracy by utilizing the advanced deep learning approach.
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