Triboelectric gait sensing analysis system for self‐powered IoT‐based human motion monitoring

Author:

Zhao Leilei12,Guo Xiao1,Pan Yusen1,Jia Shouchuang1,Liu Liqiang3,Daoud Walid A.4,Poechmueller Peter2,Yang Xiya1ORCID

Affiliation:

1. Institute of New Energy Technology, College of Information Science and Technology, Jinan University Guangzhou the People's Republic of China

2. School of Microelectronics Shandong University Jinan the People's Republic of China

3. College of Electronics and Information Engineering Tongji University Shanghai the People's Republic of China

4. Department of Mechanical Engineering City University of Hong Kong Hong Kong the People's Republic of China

Abstract

AbstractQuantitative analysis of gait parameters, such as stride frequency and step speed, is essential for optimizing physical exercise for the human body. However, the current electronic sensors used in human motion monitoring remain constrained by factors such as battery life and accuracy. This study developed a self‐powered gait analysis system (SGAS) based on a triboelectric nanogenerator (TENG) fabricated electrospun composite nanofibers for motion monitoring and gait analysis for regulating exercise programs. The SGAS consists of a sensing module, a charging module, a data acquisition and processing module, and an Internet of Things (IoT) platform. Within the sensing module, two specialized sensing units, TENG‐S1 and TENG‐S2, are positioned at the forefoot and heel to generate synchronized signals in tandem with the user's footsteps. These signals are instrumental for real‐time step count and step speed monitoring. The output of the two TENG units is significantly improved by systematically investigating and optimizing the electrospun composite nanofibers' composition, strength, and wear resistance. Additionally, a charge amplifier circuit is implemented to process the raw voltage signal, consequently bolstering the reliability of the sensing signal. This refined data is then ready for further reading and calculation by the micro‐controller unit (MCU) during the signal transmission process. Finally, the well‐conditioned signals are wirelessly transmitted to the IoT platform for data analysis, storage, and visualization, enhancing human motion monitoring.image

Funder

National Natural Science Foundation of China

Fundamental Research Funds for the Central Universities

Publisher

Wiley

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