利用高保真模拟器进行开挖中岩石运动动力学的物理信息数据驱动建模

IF 3.5 2区计算机科学 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

Simulation Modelling Practice and Theory Pub Date : 2025-09-25 DOI:10.1016/j.simpat.2025.103208

Mohammad Heravi, Amirmasoud Molaei, Reza Ghabcheloo

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引用次数: 0

摘要

本文研究了大型岩石在开挖过程中的运动预测问题。在挖掘过程中，挖掘斗、岩石和土壤之间存在复杂的相互作用，由于非线性和未知现象，分析模型无法有效地捕捉这些相互作用。为了解决这个问题，研究人员提出了一种基于物理的数据驱动框架，其中使用高保真物理模拟器获得的数据来学习岩石动力学的预测模型。具体来说，采用了物理信息神经网络，其结构为多层感知器，接收来自固定长度时间窗口的状态变量和控制输入。在损失函数中加入了一个运动约束来加强物理一致性。使用200个实验的数据对模型进行了训练和评估。研究了回顾窗口长度的影响，发现两个窗口长度产生最小的预测误差。对不同土壤和岩石情景以及不同预测层的预测误差分布进行了统计评价（1-20）。该模型的精度显示在期望的阈值之内。

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Physics-informed data-driven modeling of rock motion dynamics in excavation using a high-fidelity simulator

In this paper, the problem of predicting the motion of large rocks during excavation is addressed. During excavation, complex interactions are observed among the excavator bucket, rock, and soil, which are not effectively captured using analytical models due to nonlinearities and unknown phenomena. To address this, a physics-informed, data-driven framework is proposed, in which a predictive model of the rock dynamics is learned using data obtained from a high-fidelity physics-based simulator. Specifically, a physics-informed neural network is employed, structured as a multilayer perceptron that receives the state variables and control inputs from a fixed-length temporal window. A kinematic constraint is incorporated into the loss function to enforce physical consistency. The model is trained and evaluated using data from 200 experiments. The effect of the look-back window length is examined, and a window length of two is found to yield the minimum prediction error. The prediction error distributions are statistically evaluated for different soil and rock scenarios, as well as across different prediction horizons (1–20). The model’s accuracy is shown to be within the desired threshold.

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来源期刊

Simulation Modelling Practice and Theory 工程技术-计算机：跨学科应用

CiteScore

9.80

自引率

4.80%

发文量

142

审稿时长

21 days

期刊介绍： The journal Simulation Modelling Practice and Theory provides a forum for original, high-quality papers dealing with any aspect of systems simulation and modelling. The journal aims at being a reference and a powerful tool to all those professionally active and/or interested in the methods and applications of simulation. Submitted papers will be peer reviewed and must significantly contribute to modelling and simulation in general or use modelling and simulation in application areas. Paper submission is solicited on: • theoretical aspects of modelling and simulation including formal modelling, model-checking, random number generators, sensitivity analysis, variance reduction techniques, experimental design, meta-modelling, methods and algorithms for validation and verification, selection and comparison procedures etc.; • methodology and application of modelling and simulation in any area, including computer systems, networks, real-time and embedded systems, mobile and intelligent agents, manufacturing and transportation systems, management, engineering, biomedical engineering, economics, ecology and environment, education, transaction handling, etc.; • simulation languages and environments including those, specific to distributed computing, grid computing, high performance computers or computer networks, etc.; • distributed and real-time simulation, simulation interoperability; • tools for high performance computing simulation, including dedicated architectures and parallel computing.