Solution of Uncertain Constrained Multi-Objective Travelling Salesman Problem with Aspiration Level Based Multi Objective Quasi Oppositional Jaya Algorithm

IF 1 4区计算机科学 Q4 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

International Journal of Uncertainty Fuzziness and Knowledge-Based Systems Pub Date : 2024-04-19 DOI:10.1142/s0218488524500090

Aaishwarya Bajaj, Jayesh Dhodiya

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引用次数: 0

Abstract

Multi-Objective Travelling Salesman Problem (MOTSP) is one of the most crucial problems in realistic scenarios, and it is difficult to solve by classical methods. However, it can be solved by evolutionary methods. This paper investigates the Constrained Multi-Objective Travelling Salesman Problem (CMOTSP) and the Constrained Multi-Objective Solid Travelling Salesman Problem (CMOSTSP) under an uncertain environment with zigzag uncertain variables. To solve CMOTSP and CMOSTSP models under uncertain environment, the expected value and optimistic value models are developed using two different ranking criteria of uncertainty theory. The models are transformed to their deterministic forms using the fundamentals of uncertainty. The Models are solved using two solution methodologies Aspiration level-based Multi-Objective Quasi Oppositional Jaya Algorithm (AL-based MOQO Jaya) and Fuzzy Programming Technique (FPT) with linear membership function. Further, the numerical illustration is solved using both methodologies to demonstrate its application. The sensitivity of the OVM model’s objective functions regarding confidence levels is also investigated to look at the variation in the objective function. The paper concludes that the developed approach has solved CMOTSP and CMOSTSP efficiently with an effective output and provides alternative solutions for decision-making to DM.

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用基于愿望水平的多目标准对立伽亚算法解决不确定约束多目标旅行推销员问题

多目标旅行推销员问题（MOTSP）是现实场景中最关键的问题之一，用传统方法很难解决。然而，进化方法可以解决这一问题。本文研究了不确定环境下的受约束多目标旅行推销员问题（CMOTSP）和受约束多目标固体旅行推销员问题（CMOSTSP）。为求解不确定环境下的 CMOTSP 和 CMOSTSP 模型，利用不确定性理论的两种不同排序准则，建立了期望值模型和乐观值模型。利用不确定性的基本原理将模型转换为确定性形式。这些模型采用两种求解方法：基于期望值的多目标准对立伽亚算法（AL-based MOQO Jaya）和具有线性成员函数的模糊编程技术（FPT）。此外，还使用这两种方法进行了数值说明，以展示其应用。此外，还研究了 OVM 模型目标函数对置信度的敏感性，以了解目标函数的变化情况。本文的结论是，所开发的方法以有效的输出高效地解决了 CMOTSP 和 CMOSTSP 问题，并为 DM 的决策提供了替代解决方案。

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

International Journal of Uncertainty Fuzziness and Knowledge-Based Systems 工程技术-计算机：人工智能

CiteScore

2.70

自引率

0.00%

发文量

审稿时长

13.5 months

期刊介绍： The International Journal of Uncertainty, Fuzziness and Knowledge-Based Systems is a forum for research on various methodologies for the management of imprecise, vague, uncertain or incomplete information. The aim of the journal is to promote theoretical or methodological works dealing with all kinds of methods to represent and manipulate imperfectly described pieces of knowledge, excluding results on pure mathematics or simple applications of existing theoretical results. It is published bimonthly, with worldwide distribution to researchers, engineers, decision-makers, and educators.