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Enhancing precision in table tennis officiating through an optimized autonomous sensor node system

Chenyang Sun (Physical Education Department, Dalian Maritime University, Dalian, China)
Mohammad Khishe (Department of Electrical Engineering, Imam Khomeini Marine Science University, Nowshahr, Iran) (Innovation Center for Artificial Intelligence Applications, Yuan Ze University, Taoyuan, Taiwan) (Applied Science Research Center, Applied Science Private University, Amman, Jordan)

Engineering Computations

ISSN: 0264-4401

Article publication date: 24 September 2024

Issue publication date: 10 October 2024

25

Abstract

Purpose

The purpose of the study is to address concerns regarding the subjectivity and imprecision of decision-making in table tennis refereeing by developing and enhancing a sensor node system. This system is designed to accurately detect the points on the table tennis table where balls collide. The study introduces the twined-reinforcement chimp optimization (TRCO) framework, which combines two novel approaches to optimize the distribution of sensor nodes. The main goal is to reduce the number of sensor units required while maintaining high accuracy in determining the locations of ball collisions, with error margins significantly below the critical 3.5 mm cutoff. Through complex optimization procedures, the study aims to improve the efficiency and reliability of decision-making in table tennis refereeing by leveraging sensor technology.

Design/methodology/approach

The study employs a design methodology focused on developing a sensor array system to enhance decision-making in table tennis refereeing. It introduces the twined-reinforcement chimp optimization (TRCO) framework, combining dual adaptive weighting strategies and a stochastic approach for optimization. By meticulously engineering the sensor array and utilizing complex optimization procedures, the study aims to improve the accuracy of detecting ball collisions on the table tennis table. The methodology aims to reduce the number of sensor units required while maintaining high precision, ultimately enhancing the reliability of decision-making in the sport.

Findings

The optimization research study yielded promising outcomes, showcasing a substantial reduction in the number of sensor units required from the initial count of 60 to a more practical 49. The sensor array system demonstrated excellent accuracy in identifying the locations of ball collisions, with error margins significantly below the critical 3.5 mm cutoff. Through the implementation of the twined-reinforcement chimp optimization (TRCO) framework, which integrates dual adaptive weighting strategies and a stochastic approach, the study achieved its goal of enhancing the efficiency and reliability of decision-making in table tennis refereeing.

Originality/value

This study introduces novel contributions to the field of table tennis refereeing by pioneering the development and optimization of a sensor array system. The innovative twined-reinforcement chimp optimization (TRCO) framework, integrating dual adaptive weighting strategies and a stochastic approach, sets a new standard for sensor node distribution in sports technology. By substantially reducing the number of sensor units required while maintaining high accuracy in detecting ball collisions, this research offers practical solutions to address the inherent subjectivity and imprecision in decision-making processes. The study’s originality lies in its meticulous design methodology and complex optimization procedures, offering significant value to the field of sports technology and officiating.

Keywords

Citation

Sun, C. and Khishe, M. (2024), "Enhancing precision in table tennis officiating through an optimized autonomous sensor node system", Engineering Computations, Vol. 41 No. 8/9, pp. 2134-2168. https://doi.org/10.1108/EC-05-2024-0415

Publisher

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Emerald Publishing Limited

Copyright © 2024, Emerald Publishing Limited

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