Modeling performance evaluation in badminton sports: a fuzzy logic approach
DOI:
https://doi.org/10.56294/sctconf2024986Keywords:
Fuzzy Inference System, Neural Fuzzy, Adaptive Neuro-Fuzzy Inference System, Fuzzy LogicAbstract
Spectators and many young students have flocked to badminton matches in recent years. Badminton practice has received a lot of media coverage. The current state of badminton evaluation methods is lacking in reliability. This article's overarching goal is to examine the many applications of fuzzy logic in badminton performance evaluation and improvement. Data on the badminton technique's flexion and extension phases are mapped into the suggested model using a fuzzy inference system (FIS). This study suggests a fuzzy logic-based badminton-specific objective fuzzy inference system (Bmt-FIS) to evaluate team sports. Despite the gravity of the situation, decisions involving performance reviews often use subjective data. These common decision-making problems may be realistically addressed by fuzzy logic models. Fuzzy logic has the potential to be an effective tool in situations where both quantitative and qualitative data interpretation are allowed. To do this, it accounts for the inherent variability in athletic performance by taking into consideration the 'hazy' or 'uncertain' limitations of data. By taking limitations into account, a rule-based approach makes performance evaluation more precise. Here, a fuzzy inference system (FIS) uses the input variables to evaluate the student's performance. While data mining approaches have been studied, the adaptive neural fuzzy method outperforms others because of its exceptional accuracy.
This method eloquently and clearly conveys the many levels of integrity and ambiguity. Also, fuzzy logic may be a great tool for evaluating badminton skills. This foundational study connects the dynamic realm of sports with static measures
References
1. Taha Z, Hassan MSS, Yap HJ, Yeo WK. Preliminary investigation of an innovative digital motion analysis device for badminton athlete performance evaluation. Procedia Engineering, 147, pp. 461-465.
2. Shi W, Lai JH, Chau CK, Wong P, Edwards D. Analytic evaluation of facilities performance from the user perspective: Case study on a badminton hall. Facilities, 39(13/14), pp. 888-910.
3. van de Water T, Huijgen B, Faber I, Elferink-Gemser M. Assessing cognitive performance in badminton players: a reproducibility and validity study. Journal of Human Kinetics, 55(1), pp. 149-159.
4. Abián-Vicén J, Sánchez L, Abián P. Performance structure analysis of the men’s and women’s badminton doubles matches in the Olympic Games from 2008 to 2016 during playoffs stage. International Journal of Performance Analysis in Sport, 18(4), pp. 633-644.
5. Loureiro LDFB, Dias MOC, Cremasco FC, da Silva MG, de Freitas PB. Assessment of specificity of the badcamp agility test for badminton players. Journal of Human Kinetics, 57(1), pp. 191-198.
6. Ghosh I, Ramamurthy SR, Roy N. Stancescorer: A data driven approach to score badminton player. In 2020 IEEE international conference on pervasive computing and communications workshops (PerCom Workshops), pp. 1-6.
7. Duncan MJ, Chan CK, Clarke ND, Cox M, Smith M. The effect of badminton-specific exercise on badminton short-serve performance in competition and practice climates. European Journal of Sport Science, 17(2), pp. 119-126.
8. Hu X, Jiang Q. A study on the assessment and scoring standard of badminton course in colleges and universities: A review. Medicine, 101(49), e32230.
9. Liu H, Leng B, Li Q, Liu Y, Bao D, Cui Y. The effect of eight-week sprint interval training on aerobic performance of elite badminton players. International Journal of Environmental Research and Public Health, 18(2), pp. 638.
10. Williyanto S, Nasuka N, Kusuma DWY. The Development of Badminton Skills Test Instruments for Athletes in Age of Children, Cub, Teenager and Youth. Journal of Physical Education and Sports, 7(1), pp. 50-54.
11. Yüksel MF. A notional analysis in badminton sport: How the hit preferences affect the competition performance. Journal of Athletic Performance and Nutrition, 6(2), pp. 29-43.
12. Krizkova S, Tomaskova H, Tirkolaee EB. Sport performance analysis with a focus on racket sports: A review. Applied Sciences, 11(19), pp. 9212.
13. Torres-Luque G, Blanca-Torres JC, Giménez-Egido JM, Cabello-Manrique D, Ortega-Toro E. Design, validation, and reliability of an observational instrument for technical and tactical actions in singles badminton. Frontiers in Psychology, 11, pp. 582693.
14. Huy CV, Vu NN. Blended learning in badminton training for professionals: Students’ perceptions and performance impacts. European Journal of Physical Education and Sport Science, 6(6).
15. Hambali B, Hidayat Y, Rahmat A. Predictive validity of badminton basic skills learning outcome instrument test based on gender. In 4th International Conference on Sport Science, Health, and Physical Education (ICSSHPE 2019), pp. 373-375. Atlantis Press.
16. Subarjah H, Gilang PP, Sandey TP, Amanda PS. The Effect of Training Motivation and Emotional Intelligence on the Performance of Badminton Players. In International Conference on Education, Science and Technology, pp. 345-352. Redwhite Press.
17. Guo SZ, Mohamad NI, Zakaria J, Yu L, Abd Malek NF. Reliability and Validity of Badminton Special Speed Training Method toward Success Score and Time Perception Predictive Skills Performance of Badminton Players. In Journal of Physics: Conference Series, 1793(1), pp. 012059. IOP Publishing.
18. Zhao W, Wang C, Bi Y, Chen L. Effect of integrative neuromuscular training for injury prevention and sports performance of female badminton players. BioMed Research International, 2021, pp. 1-9.
19. Chiu YL, Tsai CL, Sung WH, Tsai YJ. Feasibility of smartphone-based badminton footwork performance assessment system. Sensors, 20(21), pp. 6035.
20. Kuo KP, Tsai HH, Lin CY, Wu WT. Verification and evaluation of a visual reaction system for badminton training. Sensors, 20(23), pp. 6808.
21. Huang P, Fu L, Zhang Y, Fekete G, Ren F, Gu Y. Biomechanical analysis methods to assess professional badminton players' lunge performance. JoVE (Journal of Visualized Experiments), 148, pp. e58842.
22. Zheng YJ, Wang WC, Chen YY, Chiu WH, Chen R, Lo CY. Wearable and wireless performance evaluation system for sports science with an example in badminton. Scientific Reports, 12(1), pp. 16855.
23. Yunwei LI, Shiwei J. Video analysis technology and its application in badminton sports training. In Journal of Physics: Conference Series, 1213(2), pp. 022009. IOP Publishing.
24. Sarwar MA, Lin YC, Daraghmi YA, İk TU, Li YL. Skeleton Based Keyframe Detection Framework for Sports Action Analysis: Badminton Smash Case. IEEE Access.
25. Rahmad NA, As’Ari MA, Soeed K, Zulkapri I. Automated badminton smash recognition using convolutional neural network on the vision based data. In IOP Conference Series: Materials Science and Engineering, 884(1), pp. 012009. IOP Publishing. https://www.kaggle.com/code/sidharkal/image-classification-with-yolov8/input
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