Performance Evaluation and Benchmarking of an Extended Computational Model of Ant Colony System for DNA Sequence Design

International journal of simulation: systems, science & technology Pub Date : 2020-12-30 DOI:10.5013/ijssst.a.15.06.06

Z. Ibrahim, M. Jusof, M. Tumari

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Abstract

Ant colony system (ACS) algorithm is one of the biologically inspired algorithms that have been introduced to effectively solve a variety of combinatorial optimisation problems. In literature, ACS has been employed to solve DNA sequence design problem. The DNA sequence design problem was modelled based on a finite state machine in which the nodes represent the DNA bases {A, C, T, G}. Later in 2011, an extended computational model of finite state machine has been employed for DNA sequence design using ACS. The performance evaluation, however, was limited. In this study, the extended computational model of finite state machine is revisited and an extensive performance evaluation is conducted using 5, 7, 10, 15, 20, 25, 30, 35, and 40 agents/ants, each with 100 independent runs. The performance of the extended computational model is also benchmarked with the existing algorithm such as a Genetic Algorithm (GA), Multi-Objective Evolutionary Algorithm (MOEA), and Particle Swarm Optimisation (PSO). Keywords-Ant Colony System, DNA Sequence Design, Finite State Machine.

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DNA序列设计中蚁群系统扩展计算模型的性能评价与基准测试

蚁群系统(ACS)算法是一种受生物学启发的算法，被引入来有效地解决各种组合优化问题。在文献中，ACS已被用于解决DNA序列设计问题。DNA序列设计问题基于有限状态机建模，其中节点代表DNA碱基{a, C, T, G}。随后在2011年，有限状态机的扩展计算模型被用于使用ACS进行DNA序列设计。然而，绩效评价是有限的。在本研究中，重新审视了有限状态机的扩展计算模型，并使用5、7、10、15、20、25、30、35和40个代理/蚂蚁进行了广泛的性能评估，每个代理/蚂蚁进行100次独立运行。扩展计算模型的性能还与现有算法(如遗传算法(GA)，多目标进化算法(MOEA)和粒子群优化(PSO))进行了基准测试。关键词:蚁群系统，DNA序列设计，有限状态机。

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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International journal of simulation: systems, science & technology

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