Abstract

Finite element model updating precision depends heavily on sufficient vibration feature extraction. However, adequate amount of sample collection is generally time-consuming in frequency response (FR) model updating. Accurate vibration feature extraction with insufficient data has become a significant challenge in FR model updating. To update the finite element model with a small dataset, a novel approach based on transfer learning is firstly proposed in this paper. A readily available fault diagnosis dataset is selected as ancillary knowledge to train a high-precision mapping from FR data to updating parameters. The proposed transfer learning network is constructed with two branches: source and target domain feature extractor. Considering about the cross-domain feature discrepancy, a domain adaptation method is designed by embedding the extracted features into a shared feature space to train a reliable model updating framework. The proposed method is verified by a simulated satellite example. The comparison results manifest that sample amount dependency has prominently lessened this method and the updated model outperforms the method without transfer learning in accuracy with the small dataset. Furthermore, the updated model is validated through dynamic response out of the training set.

Highlights

  • Model updating is an important topic in dynamic analysis and structural engineering [1,2], which is aimed at improving the finite element model reliability

  • It is observed that the methods with domain adaptation (MMDMSE and MMD2) outperform with insufficient data

  • A model updating method based on transfer learning is proposed to tackle the small dataset

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Summary

Introduction

Model updating is an important topic in dynamic analysis and structural engineering [1,2], which is aimed at improving the finite element model reliability. Frequency response (FR) is commonly regarded as the updating objective in the model updating algorithm [3,4,5]. The model updating performance overwhelmingly relies on the sample amount [6,7]. In methods based on the deep neural network [8], the requirement of the training sample amount is generally extensive. Adequate sample collection is extremely time-consuming in practice [9,10]. Insufficient data problems become a common obstacle in FR model updating [11] and reducing sample dependency would be desirable

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