Evaluation of a Microcontroller-based Smart Wearable Device in College Students' Sports Forging Application

Yong Che; Kaixuan Che; Qinlong Li

doi:10.4108/eetsis.5857

Authors

Yong Che Anyang Preschool Education College
Kaixuan Che Exercise Science School Beijing Sport University
Qinlong Li Exercise Science School Beijing Sport University

DOI:

https://doi.org/10.4108/eetsis.5857

Keywords:

smart wearable devices, university students' sports forging, application evaluation methods, zebra optimisation algorithm, convolutional neural network

Abstract

INTRODUCTION: The widespread use of smart wearable devices in various fields, including healthcare and sports, underscores the importance of their application in enhancing physical exercise among college students. Recent advancements in technology have facilitated the development of sophisticated methods to assess and predict physical activity outcomes, making their evaluation increasingly critical.
OBJECTIVES: This study aims to develop a reliable assessment model for smart wearable devices used in college students' sports activities. The objective is to accurately predict and evaluate the effectiveness of these devices in improving students' physical health and promoting lifelong sports habits. Ultimately, the research seeks to integrate advanced computational methods to enhance the accuracy of physical exercise assessments.
METHODS: The research introduces a novel assessment model that combines a zebra behavior-based heuristic optimization algorithm with a convolutional neural network (CNN). By analyzing user behavior data from wearable devices, the model constructs an evaluation index system tailored for college sports activities. The approach optimizes the parameters of the CNN using the zebra optimization algorithm, ensuring enhanced prediction accuracy.
RESULTS: The evaluation model demonstrated high accuracy, with a significant improvement in predicting the outcomes of physical exercises among college students. Comparative analyses with traditional methods revealed that the new model reduced prediction errors and increased real-time performance metrics. Specifically, the model achieved a lower root mean square error (RMSE) in simulation tests, indicating more precise assessments. Figures and statistical data provided in the study illustrate the model's superior performance across various parameters.
CONCLUSION: The developed assessment model significantly advances the application of smart wearable devices in monitoring and enhancing college students' physical activities. By integrating cutting-edge algorithms, the study not only improves the accuracy of exercise assessments but also contributes to the broader understanding of technology's role in health and fitness education. Future research could further refine this model by incorporating additional sensors and data points to expand its applicability and robustness.

References

Rana A , Srivastava V .Artificial intelligence based early detection of cardiac diseases using smart wearables[J].2022 IEEE 2nd Mysore Sub Section International Conference (MysuruCon), 2022:1-7.

Mamun A M A .Innovations in Wearable Devices: Smart Products and Wearables in Healthcare[J].Circuit cellar, 2022.

Domingo-Lopez D A , Lattanzi G , H. J S L , Wallace E J, Wylie R, O'Sullivan J. Medical devices, smart drug delivery, wearables and technology for the treatment of Diabetes Mellitus[J].Advanced drug delivery reviews, 2022:185.

Marti P , Recupero A .Body adornment and interaction aesthetics: a new frontier for assistive wearables[J].International journal of business and systems research, 2022(2):16.

Chitkesorn M A .The Marketing Factors Affecting Customer Decision-Making of Xiaomi Smart Wearable Devices in Guangxi,China[J]. Management Research:English Edition, 2022, 10(3):191-200.

Vieira D , Carvalho H , Providencia B .E-Textiles for Sports: a Systematic Review[J]. Engineering, 2022.

Zong X , Zhang C , Wu D .Research on Data Mining of Sports Wearable Intelligent Devices Based on Big Data Analysis[J].Discrete Dynamics in Nature and Society, 2022, 2022.

Vieira D , Carvalho H , Providencia B .E-Textiles for Sports: a Systematic Review[J]. Engineering, 2022.

Can Y , Member C E .Smart Affect Monitoring with Wearables in the Wild: An Unobtrusive Mood-Aware Emotion Recognition System[J].IEEE Transactions on Affective Computing, 2022.

Group T W .Freestanding membranes of 'smart' materials[J].Smart Textiles and Wearables, 2023.

Powell D , Stuart S , Godfrey A .Exploring Inertial-Based Wearable Technologies for Objective Monitoring in Sports-Related Concussion: a Single- Participant Report[J].Physical Therapy, 2022.

Hanif M A , Akram T , Shahzad A , Khan M A, Tariq U, Choi J I. Smart Devices Based Multisensory Approach for Complex Human Activity Recognition[J]. Computers, Materials and Continuum (English), 2022(2):14.

Javdan M , Ghasemaghaei M , Abouzahra M .Psychological barriers of using wearable devices by seniors: a mixed-methods study[J].Computers in Human Behavior, 2023, 141:107615-.

Atoche-Ensenat R , Perez E , Hernandez-Benitez A , Balam A, Estrada-Lopez J J. A Smart Tactile Sensing System Based on Carbon Nanotube/Polypropylene Composites for Wearable Applications[J].IEEE sensors journal, 2023.

Xinhua Z .Intelligent textiles reduce the risk of falling for the elderly[J]. China Textile:English Edition, 2022(5):27-27.

Thompson J .Smart, connected wearables help keep workers safe[J].Canadian Metalworking, 2022(2):117.

Gao Y , Ma G .Gesture recognition method for wearable sports devices based on sparse representation[J]. Development, 2023.

Kaiser M G .Digital Biomarkers and the Evolution of Spine Care Outcomes Measures: Smartphones and Wearables COMMENT[J].Neurosurgery, 2023(4):93 .

Group T W .Smart socks could transform dementia care[J].Smart Textiles and Wearables, 2023.

Group T W .Smart textiles market to advance by 25% a year[J].Smart Textiles and Wearables, 2022, 2022(Apra):11-11.

Narrendar R C , Zhen Ling T , Ting D S W .Artificial intelligence enabled smart digital eye wearables[J].Current opinion in ophthalmology, 2023(5). 34.

Eva T, Mohammad D, Pavel T. Zebra Optimization Algorithm: a New Bio-Inspired Optimisation Algorithm for Solving Optimization Algorithm[J]. IEEE Accesss, 2022, 10:49445-49473.

Sheng Tian,Lin Song. Traffic sign recognition based on CNN and Bagging integration[J]. Journal of Guangxi Normal University:Natural Science Edition, 2022, 40(4):12.

Rong-Long Wang, Lei Z , Zhang Z , Gao S. Dendritic Convolutional Neural Network[J].IEEJ Transactions on Electrical and Electronic Engineering, 2022, 17(2):302-304.

Abhyankar M S K P R .Optimal coordination of directional over-current relays using Teaching Learning-Based Optimization (TLBO) algorithm[J]. International Journal of Electrical Power & Energy Systems, 2013.

HUA Xingyue,SHAO Liangsuan. Identification of water sources of mine water burst based on KPCA-GWO-SVM[J]. Coal Mine Safety, 2023, 54(2):195-200.

Shi Jarong,Wang Shuangxin. Short-term wind power prediction based on VMD-BiLSTM-WOA[J]. Journal of Shaanxi University of Science and Technology, 2024(1):177-185.

Afshin F, Mohammad H, Seyedali M, Amir H G. Marine Predators Algorithm: a nature-inspired metaheuristic[J]. Expert Systems With Applications, 2020(152):113377.