现实交通网络的最优域划分算法及有限元网格

Q2 Engineering
Designs Pub Date : 2023-06-27 DOI:10.3390/designs7040082
Jimesh Bhagatji, S. Asundi, Eric Thompson, D. T. Nguyen
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引用次数: 0

摘要

对于大规模工程问题,领域划分算法是通用有限元分析(FEA)的理想选择,这已被普遍接受。本文提出了一种启发式数值算法,该算法可以有效地将任何运输网络(或任何有限元网格)划分为指定数量的子域(通常取决于计算机上可用的并行处理器数量),这将导致“最小化系统边界节点总数”(作为主要标准)并在子域之间实现“平衡工作负载”(作为次要标准)。提出了一种基于工程常识和观察的七步启发式算法(具有增强特征)。目前的工作具有以下新颖性特点:(i)不需要复杂的图理论;(ii)可以通过将原始网络(或FE网格)转换为仅使用线元素的伪运输网络来实现运输网络(使用线元素)和有限元(FE)网格(使用三角形、四面体和砖元素)的统一处理。几个例子,包括现实生活中的交通网络和有限元网格(使用三角形/砖/四面体单元)被使用(在MATLAB计算机环境下)来解释,验证和比较所提出的算法与流行的METIS软件的性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optimal Domain-Partitioning Algorithm for Real-Life Transportation Networks and Finite Element Meshes
For large-scale engineering problems, it has been generally accepted that domain-partitioning algorithms are highly desirable for general-purpose finite element analysis (FEA). This paper presents a heuristic numerical algorithm that can efficiently partition any transportation network (or any finite element mesh) into a specified number of subdomains (usually depending on the number of parallel processors available on a computer), which will result in “minimising the total number of system BOUNDARY nodes” (as a primary criterion) and achieve “balancing work loads” amongst the subdomains (as a secondary criterion). The proposed seven-step heuristic algorithm (with enhancement features) is based on engineering common sense and observation. This current work has the following novelty features: (i) complicated graph theories that are NOT needed and (ii) unified treatments of transportation networks (using line elements) and finite element (FE) meshes (using triangular, tetrahedral, and brick elements) that can be performed through transforming the original network (or FE mesh) into a pseudo-transportation network which only uses line elements. Several examples, including real-life transportation networks and finite element meshes (using triangular/brick/tetrahedral elements) are used (under MATLAB computer environments) to explain, validate and compare the proposed algorithm’s performance with the popular METIS software.
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来源期刊
Designs
Designs Engineering-Engineering (miscellaneous)
CiteScore
3.90
自引率
0.00%
发文量
0
审稿时长
11 weeks
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