基于深度学习的Taylor杆碰撞数值模拟算法

doi:10.11871/jfdc.issn.2096-742X.2025.06.010

数据与计算发展前沿 ›› 2025, Vol. 7 ›› Issue (6): 101-110.

CSTR: 32002.14.jfdc.CN10-1649/TP.2025.06.010

doi: 10.11871/jfdc.issn.2096-742X.2025.06.010

基于深度学习的Taylor杆碰撞数值模拟算法

杨沁蒙¹(),聂宁明^1,²,周纯葆^1,²,王彦棡^1,^2,^*()

1.中国科学院计算机网络信息中心，北京 100083
2.中国科学院大学，北京 100049

出版日期:2025-12-20 发布日期:2025-12-17
通讯作者: 王彦棡
作者简介:杨沁蒙，中国科学院计算机网络信息中心，助理研究员，主要研究方向为人工智能模型应用，自然语言处理，跨学科应用等。
本文主要承担工作为数据处理，实验设计，模型构建及学习训练。
YANG Qinmeng is an assistant researcher at the Computer Network Information Center, Chinese Academy of Sciences. His research interests include applications of artificial intelligence models, natural language processing, and interdisciplinary applications.
In this paper, he is responsible for data processing, experimental design, model construction and training.
E-mail: qmyang@cnic.cn|王彦棡，中国科学院计算机网络信息中心，研究员，主要研究方向为人工智能算法与应用软件。
本文主要承担工作为思路凝练和论文的指导。
WANG Yangang is a professor at the Computer Network Information Center, Chinese Academy of Sciences. His research interests include artificial intelligence algorithms and application software.
In this paper, he is responsible for refining the research ideas and the guidance of the paper.
E-mail: wangyg@sccas.cn
基金资助:
高性能计算可扩展多级并行开发及毁伤效应数值仿真大规模算例验证(O2021A14243)

Algorithm for Taylor Bar Collision Data Simulation Based on Deep Learning

YANG Qinmeng¹(),NIE Ningming^1,²,ZHOU Chunbao^1,²,WANG Yangang^1,^2,^*()

1. Computer Network Information Center, Chinese Academy of Sciences, Beijing 100083, China
2. University of Chinese Academy of Sciences, Beijing 100049, China

Online:2025-12-20 Published:2025-12-17
Contact: WANG Yangang

摘要/Abstract

摘要：

【目的】在超高速碰撞问题求解过程中，通常面临物质变形大、模拟难度大、计算成本高等问题。近年，随着深度学习的发展，融合物理知识神经网络方法的出现，为超高速碰撞问题的高效求解带来了新思路。【方法】本文设计并实现了针对超高速碰撞过程精确模拟算法，利用神经网络学习算子间复杂的非线性映射关系与变化趋势，融合物理先验知识，学习预测与真实算子间的差距，设计损失函数，实现算法对各个算子的精确模拟。【结果】通过Taylor杆碰撞算例进行算法测试，测试结果显示对算子拟合的误差率低于20%。【局限】超高速碰撞问题还有更多的案例，通过学习更多的相关案例可以提高算法的应用范围。【结论】本文实现了基于深度学习神经网络并结合物理知识的Taylor杆碰撞模拟算法，获得良好预测效果。

关键词: 深度学习, PINN, Taylor杆碰撞, 算子, 数据驱动, 科研范式

Abstract:

[Objective] In the process of solving ultra-high-speed collision problems, challenges such as significant material deformations and high computational costs are commonly encountered. In recent years, with the development of deep learning and the emergence of neural networks that incorporate physics knowledge, new ideas have been brought for the efficient solution of such problems. [Methods] This paper designs and implements an accurate simulation algorithm for ultra-high-speed collision problems, neural networks are used to learn the complex nonlinear mapping relationships between operators, thoroughly understanding the trends in changes among these operators. Based on this, physical prior knowledge is integrated, and the algorithm learns to predict and quantify the discrepancy between the predicted and real operators. A loss function is designed to achieve accurate simulation of each operator. [Results] Focusing on the Taylor bar collision case in ultra-high-speed collision problems, the error rate of operator fitting is less than 20%. [Limitations] There are many more cases in ultra-high-speed collision problems. By learning from a broader range of related cases, the applicability of the algorithm can be enhanced. [Conclusions] This paper designs a Taylor bar collision simulation algorithm based on deep learning neural networks combined with physical knowledge, and achieves good predictive performance.

Key words: deep learning, PINN, Taylor bar collision, operator, data-driven, scientific paradigm

杨沁蒙,聂宁明,周纯葆,王彦棡. 基于深度学习的Taylor杆碰撞数值模拟算法[J]. 数据与计算发展前沿, 2025, 7(6): 101-110.

YANG Qinmeng,NIE Ningming,ZHOU Chunbao,WANG Yangang. Algorithm for Taylor Bar Collision Data Simulation Based on Deep Learning[J]. Frontiers of Data and Computing, 2025, 7(6): 101-110, https://cstr.cn/32002.14.jfdc.CN10-1649/TP.2025.06.010.

图/表 9

图1

图2

图3

图4

表1

图5

图6

图7

图8

参考文献 27

[1]	马上, 张雄, 邱信明. 超高速碰撞问题的三维物质点法[J]. 爆炸与冲击, 2006(3): 273-278.
[2]	RAISSI M, PERDIKARIS P, KARNIADAKIS G E. Physics Informed Deep Learning (Part II): Data-driven Discovery of Nonlinear Partial Differential Equations[EB/OL]. (2017-11-01). https://arxiv.org/abs/1711.10566.
[3]	RAISSI M, PERDIKARIS P, KARNIADAKIS G E. Numerical Gaussian Processes for Time-Dependent and Nonlinear Partial Differential Equations[J]. SIAM Journal on Scientific Computing, 2018, 40: A172-A198.
[4]	RAISSI M, KARNIADAKIS G E. Hidden physics models: Machine learning of nonlinear partial differential equations[J]. Journal of Computational Physics, 2018, 357(C): 125-141.
[5]	HAN J Q, JENTZEN A, E W N. Solving high-dimensional partial differential equations using deep learning[J]. Proceedings of the National Academy of Sciences of the United States of America, 2018, 115(34): 8505-8510.
[6]	WEINAN E, HAN J Q, JENTZEN A. Deep Learning-Based Numerical Methods for High-Dimensional Parabolic Partial Differential Equations and Backward Stochastic Differential Equations[J]. Communications in Mathematics and Statistics, 2017, 5: 349-380.
[7]	NABIAN M A, MEIDANI H. A deep learning solution approach for high-dimensional random differential equations[J]. Probabilistic Engineering Mechanics, 2019, 57: 14-25.
[8]	WEINAN E, MA C, WOJTOWYTSCH S, et al. Towards a Mathematical Understanding of Neural Network-Based Machine Learning: what we know and what we don’t[EB/OL]. (2020-12-07). https://doi.org/10.48550/arXiv.2009.10713
[9]	ZHA W S, ZHANG W, LI D L, et al. Convolution-Based Model-Solving Method for Three-Dimensional, Unsteady, Partial Differential Equations[J]. Neural Computation, 2022, 34: 518-540.
[10]	MENG X H, LI Z, ZHANG D K, et al. PPINN: Parareal physics-informed neural network for time-dependent PDEs[J]. Computer Methods in Applied Mechanics and Engineering. 2020, 370.
[11]	MICHOSKI C, MILOSAVLJEVIĆ M, OLIVER T, et al. Solving Differential Equations using Deep Neural Networks[J]. 2020, 399: 193-212.
[12]	NAGOOR KANI J, ELSHEIKH A H. Reduced-Order Modeling of Subsurface Multi-phase Flow Models Using Deep Residual Recurrent Neural Networks[J]. Transp Porous Med, 2019, 126: 713-741.
[13]	JAGTAP A D, KAWAGUCHI K, KARNIADAKIS G E. Adaptive activation functions accelerate convergence in deep and physics-informed neural netorks[J]. Journal of Computational Physics, 2020, 404(C): 109136.
[14]	JAGTAP A D, KAWAGUCHI K, KARNIADAKIS G E. Locally adaptive activation functions with slope recovery for deep and physics-informed neural networks[J]. Proceedings of The Royal Society A: Mathematical Physical and Engineering Sciences, 2020, 476(2239).
[15]	WANG N Z, ZHANG D X, CHANG H B, et al. Deep learning of subsurface flow via theory-guided neural network[J]. Journal of Hydrology, 2020, 584: 124700.00
[16]	WANG N Z, CHANG H B, ZHANG D X. Theory-guided Auto-Encoder for surrogate construction and inverse modeling[J]. Computer Methods in Applied Mechanics and Engineering, 2021, 385: 114037.
[17]	LI D L, SHEN L H, ZHA W S, et al. Physics-constrained deep learning for solving seepage equa-tion[J]. Journal of Petroleum Science and Engineering, 2021, 206: 109046.
[18]	ABOUALI S. Application of Physics-Informed Neural Network to Calibration of a Damage-Plasticity Material Model for Composites[D]. Vancouver: University of British Columbia, 2024.
[19]	LU L, JIN P Z, PANG G F, et al. Learning nonlinear operators via DeepONet based on the universal approximation theorem of operators[J]. Nature Machine Intelligence, 2021, 3: 218-229.
[20]	LI Z Y, KOVACHKI N B, AZIZZADENESHELI K, et al. Fourier neural operator for parametric partial differential equations[C]. International Conference on Learning Representations, 2021.
[21]	MAO Z P, LU L, MARXEN O, et al. DeepM&Mnet for hypersonics: Predicting the coupled flow and finite-rate chemistry behind a normal shock using neural-network approximation of operators[J]. Journal of Computational Physics, 2021, 447: 110698.
[22]	HE J Y, KORIC S, KUSHWAHA S, et al. Novel DeepONet architecture to predict stresses in elastoplastic structures with variable complex geometries and loads[J]. Computer Methods in Applied Mechanics and Engineering, 2023, 415: 116277.
[23]	LI W, BAZANT M, ZHU J. Phase-Field DeepONet: Physics-informed deep operator neural network for fast simulations of pattern formation governed by gradient flows of free-energy functionals[J]. Computer Methods in Applied Mechanics and Engineering, 2023, 416: 116299.
[24]	CHEN X X, ZHANG P, YIN Z Y. Physics-Informed neural network solver for numerical analysis in geoengineering[J]. Georisk: Assessment and Management of Risk for Engineered Systems and Geohazards, 2024, 18: 33-51.
[25]	WANG M Z, WANG Q, ZAKI T. Discrete adjoint of fractional-step incompressible Navier-Stokes solver in curvilinear coordinates and application to data assimilation[J]. Journal of Computational Physics, 2019, 396: 427-450.
[26]	TAYLOR G. The use of flat-ended projectiles for determining dynamic yield stress I. Theoretical considerations[J]. Proceedings of The Royal Society A: Mathematical, Physical and Engineering Sciences, 1948, 194: 289-299.
[27]	JASRA Y, SAXENA R. Numerical simulation of fracture in Taylor rod impact problem with stochastically distributed inherent damage[J]. International Journal for Computational Methods in Engineering Science and Mechanics, 2023, 24: 1-23.

类型	硬件配置/依赖包
处理器	国产x86处理器
操作系统	Linux CentOS 7.6.1810
依赖环境	Cmake-3.16版本及以上
	Zlib-1.6.6版本及以上
	Szip-2.1版本及以上
	Hdf5-1.8.9版本及以上
	H5part-1.6.6版本及以上
	Qt-4.5.3版本或Qt5版本
	P4est-2.8版本
	Gmsh-v4.1.2版本及以上
编程语言	Python-3.9.12
神经网络训练环境包	Numpy-1.19.5
	Pandas-1.4.1
	Scikit-learn-1.0.2
	Tensorflow-2.5.0
	DeepXde-0.11.2

基于深度学习的Taylor杆碰撞数值模拟算法

Algorithm for Taylor Bar Collision Data Simulation Based on Deep Learning

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

图/表 9

参考文献 27

相关文章 15

编辑推荐

Metrics

本文评价

[1]	周法国,刘芳,王彦棡,王珏,于淼,李顺德,周纯葆,王婧,杨沁蒙. 面向国产超算的深度学习框架算子的移植与适配[J]. 数据与计算发展前沿, 2025, 7(6): 136-148.
[2]	令狐荣微,张瑜,石元泉,杨玉军. 基于多特征融合的PE恶意代码检测与分类研究[J]. 数据与计算发展前沿, 2025, 7(6): 77-91.
[3]	辛昱杭,王琦祎,孙婧,赵春燕,刘雨佳,梁雪,陈杰. 基于雷达回波外推的短临降水预报模型TrajCast在国产加速器上的实践[J]. 数据与计算发展前沿, 2025, 7(5): 113-122.
[4]	王鹏,杨霄凤,何忠臣,杜君. 基于浅层-深层卷积循环神经网络的多光谱遥感图像全色锐化方法[J]. 数据与计算发展前沿, 2025, 7(5): 138-152.
[5]	曾艳,吴宝福,易广政,黄成创,邱扬,陈越,万健,胡帆,金思聪,梁迦隽,李欣. FlowAware：一种支持AI for Science任务的模型分布式自动并行方法[J]. 数据与计算发展前沿, 2025, 7(5): 65-87.
[6]	贾子昂. 基于多源半监督学习的牙齿结构分割[J]. 数据与计算发展前沿, 2025, 7(2): 175-185.
[7]	马秋平, 张琪, 赵晓凡. 图表问答研究综述[J]. 数据与计算发展前沿, 2025, 7(1): 19-37.
[8]	水映懿, 张琪, 李根, 张士豪, 吴尚. 基于多类特征的社交网络影响力预测研究综述[J]. 数据与计算发展前沿, 2025, 7(1): 2-18.
[9]	金家立, 高思远, 高满达, 王文彬, 柳绍祯, 孙哲南. 基于生成对抗网络和扩散模型的人脸年龄编辑综述[J]. 数据与计算发展前沿, 2025, 7(1): 38-55.
[10]	卢成浩,陈秀宏. 基于隐式分区学习深度特征融合重建曲面网络[J]. 数据与计算发展前沿, 2024, 6(6): 19-31.
[11]	汪洋,周小军,魏鑫,褚大伟,郑晓欢,彭颖,冷伏海,张凤,丛培民,吉志霞,廖方宇. 大数据驱动下的科研机构科研治理创新实践[J]. 数据与计算发展前沿, 2024, 6(6): 43-52.
[12]	韦一金,樊景超. 基于改进的BERT-BiGRU-Attention的农业科技政策分类模型[J]. 数据与计算发展前沿, 2024, 6(6): 53-61.
[13]	何文通,罗泽. 基于联邦学习的野生动物红外相机图像目标检测[J]. 数据与计算发展前沿, 2024, 6(6): 85-96.
[14]	晏直誉, 茹一伟, 孙福鹏, 孙哲南. 基于主动感知机制的视频行为识别方法研究[J]. 数据与计算发展前沿, 2024, 6(5): 66-79.
[15]	廖立波, 王书栋, 宋维民, 张兆领, 李刚, 黄永盛. CEPC上基于DeepSets模型的喷注标记算法研究[J]. 数据与计算发展前沿, 2024, 6(3): 108-115.