Intelligent contributions of the artificial orca algorithm for continuous problems and real-time emergency medical services.

IF 2.3 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Evolutionary Intelligence Pub Date : 2023-04-21 DOI:10.1007/s12065-023-00846-y

Lydia Sonia Bendimerad, Habiba Drias

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引用次数: 1

Abstract

The Artificial Orca Algorithm (AOA) is an existing swarm intelligence algorithm, empowered in this paper by two well-known mutation operators and opposition-based learning, yielding the novel methods Deep Self-Learning Artificial Orca Algorithm (DSLAOA), Opposition Deep Self-Learning Artificial Orca Algorithm (ODSLAOA), and Opposition Artificial Orca Learning Algorithm. The DSLAOA and ODSLAOA are based on the Cauchy and Gauss mutation operators. Their effectiveness is evaluated on both continuous and discrete problems. The suggested algorithms are tested and compared to seven recent state-of-the-art metaheuristics in the continuous context. The results demonstrate that, when compared to the other algorithms, DSLAOA based on the Cauchy operator is the most effective technique. After that, a specific real-world scenario involving emergency medical services in a dire situation is tackled. The Ambulance Dispatching and Emergency Calls Covering Problem is the addressed problem, and a mathematical formulation is made to model this issue. AOA, DSLAOAC, and DSLAOAG are tested and contrasted with a successful recent heuristic in this field. The experiments are run on real data, and the results show that the swarm approaches are effective and helpful in determining the resources required in this kind of emergency.

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人工orca算法对连续问题和实时紧急医疗服务的智能贡献。

人工奥卡算法（AOA）是一种现有的群体智能算法，本文通过两种著名的变异算子和基于对立的学习，产生了深度自学习人工奥卡法（DSLAOA）、对立深度自学习算法（ODSLOA）和对立人工奥卡学习算法。DSLAOA和ODSLAOA是基于Cauchy和Gauss变异算子的。它们的有效性在连续问题和离散问题上都得到了评估。在连续上下文中，对所提出的算法进行了测试，并与最近七种最先进的元启发式算法进行了比较。结果表明，与其他算法相比，基于柯西算子的DSLAOA是最有效的技术。之后，一个涉及紧急医疗服务的特定现实场景将被处理。救护车调度和紧急呼叫覆盖问题是已解决的问题，并对该问题进行了数学建模。对AOA、DSLAOAC和DSLAOAG进行了测试，并与该领域最近成功的启发式算法进行了对比。实验是在真实数据上进行的，结果表明，群体方法在确定此类紧急情况下所需的资源方面是有效和有帮助的。

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

Evolutionary Intelligence COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-

CiteScore

6.80

自引率

0.00%

发文量

108

期刊介绍： This Journal provides an international forum for the timely publication and dissemination of foundational and applied research in the domain of Evolutionary Intelligence. The spectrum of emerging fields in contemporary artificial intelligence, including Big Data, Deep Learning, Computational Neuroscience bridged with evolutionary computing and other population-based search methods constitute the flag of Evolutionary Intelligence Journal.Topics of interest for Evolutionary Intelligence refer to different aspects of evolutionary models of computation empowered with intelligence-based approaches, including but not limited to architectures, model optimization and tuning, machine learning algorithms, life inspired adaptive algorithms, swarm-oriented strategies, high performance computing, massive data processing, with applications to domains like computer vision, image processing, simulation, robotics, computational finance, media, internet of things, medicine, bioinformatics, smart cities, and similar. Surveys outlining the state of art in specific subfields and applications are welcome.

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