An efficient uncertain chance constrained geometric programming model based on value-at-risk for truss structure optimization problems

IF 2.1 2区数学 Q1 MATHEMATICS, APPLIED

Journal of Computational and Applied Mathematics Pub Date : 2024-11-07 DOI:10.1016/j.cam.2024.116347

Jie Chen, Haoxuan Li, Xiangfeng Yang

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引用次数: 0

Abstract

Uncertain geometric programming is a type of geometric programming involving uncertain variables. As described in the literature, the uncertain geometric programming model based on expected value cannot reflect the risk preference of decision-makers. It motivates us to establish an uncertain geometric programming model based on value-at-risk to describe the risk level that managers can tolerate. Firstly, we propose the uncertain geometric programming model based on value-at-risk. Then, according to the operational law in uncertainty theory, this model is transformed into a crisp and equivalent form. Three numerical examples are used to verify the model’s efficacy, and the paper emphasizes the influence of confidence level in the objective function and the constraints. In addition, the paper discusses the expected value model under an uncertain environment and presents the difference between expected value and value-at-risk. Finally, we apply the model to the problem of a two-bar truss, and the optimal solution can be obtained within the risk level that the structural designer can accept.

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基于风险价值的桁架结构优化问题的高效不确定机会约束几何程序设计模型

不确定几何程序设计是一种涉及不确定变量的几何程序设计。如文献所述，基于期望值的不确定几何程序设计模型无法反映决策者的风险偏好。这促使我们建立基于风险值的不确定几何程序设计模型，以描述管理者可容忍的风险水平。首先，我们提出了基于风险价值的不确定几何程序模型。然后，根据不确定性理论中的运算法则，将该模型转化为清晰的等价形式。本文通过三个数值实例验证了模型的有效性，并强调了置信度对目标函数和约束条件的影响。此外，本文还讨论了不确定环境下的期望值模型，并介绍了期望值与风险值之间的区别。最后，我们将该模型应用于双杆桁架问题，并在结构设计师可接受的风险水平内获得最优解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Computational and Applied Mathematics 数学-应用数学

CiteScore

5.40

自引率

4.20%

发文量

437

审稿时长

3.0 months

期刊介绍： The Journal of Computational and Applied Mathematics publishes original papers of high scientific value in all areas of computational and applied mathematics. The main interest of the Journal is in papers that describe and analyze new computational techniques for solving scientific or engineering problems. Also the improved analysis, including the effectiveness and applicability, of existing methods and algorithms is of importance. The computational efficiency (e.g. the convergence, stability, accuracy, ...) should be proved and illustrated by nontrivial numerical examples. Papers describing only variants of existing methods, without adding significant new computational properties are not of interest. The audience consists of: applied mathematicians, numerical analysts, computational scientists and engineers.