Hierarchical MPM-ANN Multiscale Terrain Model for High-Fidelity Off-Road Mobility Simulations: A Coupled MBD-FE-MPM-ANN Approach

IF 1.9 4区 工程技术 Q3 ENGINEERING, MECHANICAL
Guanchu Chen, Hiroki Yamashita, Y. Ruan, P. Jayakumar, D. Gorsich, J. Knap, K. Leiter, Xiaobo Yang, H. Sugiyama
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引用次数: 1

Abstract

A new hierarchical multiscale terrain model is developed using the material point method (MPM) to enable effective modeling of large terrain deformation for high-fidelity off-road mobility simulations. Unlike the Lagrangian finite-element model, MPM allows for modeling large deformation of a continuum without mesh distortion using material points as moving quadrature points for the background grid. This unique feature is extended to account for complex granular soil material behavior with the hierarchical multiscale modeling approach in the context of off-road mobility simulations. The grain-scale discrete-element (DE) representative volume element (RVE) and its neural network surrogate model (ANN) are developed and introduced to the upper-scale MPM model through the scale-bridging algorithm. The DE RVE is used to generate training data for the ANN RVE, allowing for predicting the history-dependent grain-scale soil material behavior efficiently at every material point that moves through the upper-scale MPM background grid. A numerical procedure for modeling the interaction of the nonlinear FE tire model with the MPM-ANN multiscale terrain model is developed considering moving soil patches generalized for the upper-scale MPM terrain model. It is fully integrated into the general off-road mobility simulation framework by leveraging scalable high-performance computing techniques. The predictive ability of the proposed MPM-ANN multiscale off-road mobility model is examined and validated against the full-scale vehicle test data, involving large deformation of soft terrain. The computational benefit from the neural network surrogate model is also demonstrated.
高保真越野机动模拟的分层MPM-ANN多尺度地形模型:MBD-FE-MPM-ANN耦合方法
为了实现高保真越野机动仿真中大地形变形的有效建模,采用物质点法建立了一种新的分层多尺度地形模型。与拉格朗日有限元模型不同,MPM允许使用材料点作为背景网格的移动正交点来模拟连续体的大变形而不产生网格畸变。这种独特的特征被扩展到考虑复杂的颗粒土材料行为与层次多尺度建模方法在越野机动模拟的背景下。通过尺度桥接算法,将粒度离散元(DE)代表体积元(RVE)及其神经网络代理模型(ANN)引入到上尺度MPM模型中。DE RVE用于为ANN RVE生成训练数据,允许在通过上层尺度MPM背景网格的每个物质点上有效地预测依赖历史的粒度土壤物质行为。考虑上尺度MPM地形模型推广的移动土壤斑块,提出了一种模拟非线性有限元轮胎模型与MPM- ann多尺度地形模型相互作用的数值方法。通过利用可扩展的高性能计算技术,它完全集成到一般的越野移动模拟框架中。针对软地形大变形的全尺寸车辆试验数据,验证了所提出的MPM-ANN多尺度越野机动模型的预测能力。神经网络代理模型的计算效益也得到了验证。
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来源期刊
CiteScore
4.00
自引率
10.00%
发文量
72
审稿时长
6-12 weeks
期刊介绍: The purpose of the Journal of Computational and Nonlinear Dynamics is to provide a medium for rapid dissemination of original research results in theoretical as well as applied computational and nonlinear dynamics. The journal serves as a forum for the exchange of new ideas and applications in computational, rigid and flexible multi-body system dynamics and all aspects (analytical, numerical, and experimental) of dynamics associated with nonlinear systems. The broad scope of the journal encompasses all computational and nonlinear problems occurring in aeronautical, biological, electrical, mechanical, physical, and structural systems.
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