Vehicle Crashworthiness Performance Prediction through Fusion of Multiple Data Sources

IF 2.9 3区 工程技术 Q2 ENGINEERING, MECHANICAL
Jice Zeng, Ying Zhao, Guosong Li, Zhenyan Gao, Yang Li, Saeed Barbat, Zhen Hu
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引用次数: 0

Abstract

This study aims at improving the prediction accuracy of the Computer-Aided Engineering (CAE) model for crashworthiness performance evaluation at speeds beyond those defined by current regulations and public domain testing protocols. In this study, two scenarios are investigated: (1) improving CAE model prediction accuracy using test data of a vehicle type that is the same as that of the CAE model; (2) improving CAE model prediction accuracy using test data from two different types of vehicles (e.g., two different sizes of SUVs). In the first scenario, a novel approach is proposed in the displacement domain (deceleration vs. displacement) to enable data fusion to help recover the unmodeled physics in the CAE model. A nonlinear spring-mass model is used to simulate rigid-barrier vehicle frontal impact. A Gaussian process regression (GPR) model is then applied in conjunction with a Gaussian mixture model to capture the model bias of the nonlinear spring constant. In the second scenario, we propose a time domain method (deceleration vs. time) based on temporal convolutional network (TCN) and transfer learning. An initial TCN model is first trained by fusing CAE data with physical test data of the first vehicle type based on data augmentation. This data-augmented TCN model is then fine-tuned through transfer learning using CAE and test data of the second vehicle type. Cased studies are used to validate the proposed approaches, and to demonstrate their efficacy in improving the prediction accuracy of the CAE models.
通过融合多种数据源预测车辆耐撞性能
本研究旨在提高计算机辅助工程(CAE)模型的预测精度,以便在速度超过现行法规和公共领域测试协议规定的速度时进行防撞性能评估。本研究调查了两种情况:(1) 使用与 CAE 模型相同类型车辆的测试数据提高 CAE 模型的预测精度;(2) 使用两种不同类型车辆(如两种不同尺寸的 SUV)的测试数据提高 CAE 模型的预测精度。在第一种情况下,在位移域(减速与位移)提出了一种新方法,以实现数据融合,帮助恢复 CAE 模型中未建模的物理特性。使用非线性弹簧-质量模型模拟刚性壁障车辆的正面碰撞。然后将高斯过程回归 (GPR) 模型与高斯混合模型结合使用,以捕捉非线性弹簧常数的模型偏差。在第二种方案中,我们提出了一种基于时序卷积网络(TCN)和迁移学习的时域方法(减速与时间)。首先,在数据增强的基础上,将 CAE 数据与第一种车型的物理测试数据融合,从而训练出一个初始 TCN 模型。然后利用第二种车型的 CAE 和测试数据,通过迁移学习对这一数据增强的 TCN 模型进行微调。案例研究用于验证所提出的方法,并证明其在提高 CAE 模型预测准确性方面的功效。
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来源期刊
Journal of Mechanical Design
Journal of Mechanical Design 工程技术-工程:机械
CiteScore
8.00
自引率
18.20%
发文量
139
审稿时长
3.9 months
期刊介绍: The Journal of Mechanical Design (JMD) serves the broad design community as the venue for scholarly, archival research in all aspects of the design activity with emphasis on design synthesis. JMD has traditionally served the ASME Design Engineering Division and its technical committees, but it welcomes contributions from all areas of design with emphasis on synthesis. JMD communicates original contributions, primarily in the form of research articles of considerable depth, but also technical briefs, design innovation papers, book reviews, and editorials. Scope: The Journal of Mechanical Design (JMD) serves the broad design community as the venue for scholarly, archival research in all aspects of the design activity with emphasis on design synthesis. JMD has traditionally served the ASME Design Engineering Division and its technical committees, but it welcomes contributions from all areas of design with emphasis on synthesis. JMD communicates original contributions, primarily in the form of research articles of considerable depth, but also technical briefs, design innovation papers, book reviews, and editorials.
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