Optimization of Loneys Solenoid Design Using a Dynamic Search Based Technique

Authors

  • Shanshan Tu Department of Computer Science, Beijing University of Technology, Beijing, 10024, China
  • Obaid U. Rehman Department of Electrical Engineering, Sarhad University of Science and IT, Peshawar, 25000, Pakistan
  • Sadaqat U. Rehman Department of Computer Science, Namal Institute, Mianwali, 42250, Pakistan
  • Shafi U. Khan Department of Electronics, Islamia College University, Peshawar, 25000, Pakistan
  • Muhammad Waqas Department of Computer Science & Engineering Ghulam Ishaq Khan Institute of Engineering Sciences & Technology, Topi, 23460, Pakistan
  • Ajmal Farooq Department of Electrical Engineering, UET Mardan, Mardan, 25000, Pakistan

Keywords:

Design optimization, probability distribution, quantum mechanics, searched based technique

Abstract

Particle swarm optimizer is one of the searched based stochastic technique that has a weakness of being trapped into local optima. Thus, to tradeoff between the local and global searches and to avoid premature convergence in PSO, a new dynamic quantumbased particle swarm optimization (DQPSO) method is proposed in this work. In the proposed method a beta probability distribution technique is used to mutate the particle with the global best position of the swarm. The proposed method can ensure the particles to escape from local optima and will achieve the global optimum solution more easily. Also, to enhance the global searching capability of the proposed method, a dynamic updated formula is proposed that will keep a good balance between the local and global searches. To evaluate the merit and efficiency of the proposed DQPSO method, it has been tested on some well-known mathematical test functions and a standard benchmark problem known as Loney’s solenoid design.

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Published

2021-01-08

How to Cite

[1]
Shanshan Tu, Obaid U. Rehman, Sadaqat U. Rehman, Shafi U. Khan, Muhammad Waqas, and Ajmal Farooq, “Optimization of Loneys Solenoid Design Using a Dynamic Search Based Technique”, ACES Journal, vol. 36, no. 1, pp. 35–40, Jan. 2021.

Issue

2021: Vol 36 Iss 1

Section

Articles