Survey on EcoStride Power Generation System Harnessing for Sustainable Energy


Authors : Varshitha M K; Karthik B R; Khushi D P ; Kavya Kosigi

Volume/Issue : Volume 9 - 2024, Issue 12 - December

Google Scholar : https://tinyurl.com/2h3wb89w

Scribd : https://tinyurl.com/mvbhh8k2

DOI : https://doi.org/10.5281/zenodo.14511858

Abstract : Footsteps, a ubiquitous source of mechanical energy, present a unique opportunity for sustainable power generation. With increasing mobile device dependency, this innovative approach addresses the challenge of eco-friendly energy solutions.Public spaces, especially high-footfall areas, provide an ideal setting for implementing such systems, benefiting users and reducing energy reliance. This study introduces a system that leverages piezoelectric sensors integrated into flooring to harvest energy from footsteps and convert it into electricity. The addition of RFID technology ensures that access to the stored energy is secure and authenticated for purposes like mobile charging. Notable features include effective energy conversion, real-time energy usage tracking, and secure access via RFID-based authentication. By utilizing renewable energy sources, the system aims to lower environmental impact and support sustainable practices in urban infrastructure.

Keywords : Footstep Power, RFID, Renewable Energy, Mobile Charging, Piezoelectric Sensors, Sustainable Energy, Eco-Friendly Solutions, Real-Time Monitoring.

References :

  1. 2021. This paper proposes a novel approach for integrating RFID with footstep-based power systems to enhance security
  2. A. Saumya, V. Gayathri, K. Venkateswaran, S. Kale, and N. and energy storage management. Sridhar, "Footstep Energy Harvesting for Mobile Charging in Public Spaces Using RFID Authentication," presented at the 2021 International Conference on Sustainable Energy Systems (ICSES).
  3. W. Riaz, A. Azeem, G. Chenqiang, Z. Yuxi, S. Waqas, and K. Khalid, "Enhancing Footstep Power Generation with RFID- Based Energy Access Control," presented at the 2021 IEEE International Conference on Green Technology and Applications (GTA)
  4. Z. Rahman, A. M. Ami, and M. A. Ullah, "Real-Time Footstep Energy Harvesting and RFID Authentication System for Urban Spaces," in 2021 IEEE Region 10 Symposium (TENSYMP).
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  12. W. Riaz, A. Azeem, G. Chenqiang, Z. Yuxi, S. Waqas, and K. Khalid “RFID-Controlled Footstep Power Generation.
  13. P. S. Reddy, T. Nishwa, R. S. Kiran Reddy, C. Sadviq, and K. Rithvik, "Machine Learning for Footstep Energy Harvesting Optimization," 2021. This study explores machine learning applications for optimizing footstep power generation and its integration with RFID for efficient energy distribution.
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  20. M. Nyamesah and C. Kusi, “Real-Time Footstep Energy Harvesting for Mobile Charging with RFID Authentication,” 2024. This study emphasizes the real-time monitoring and management of footstep-powered charging systems, incorporating RFID technology to ensure secure user access
  21. L. Zhang, Y. Li, W. Chen, and H. Wang, “Piezoelectric and RFID-Based Smart Footstep Energy Harvesting Systems for Sustainable Urban Mobility,” 2022. This study explores the combination of piezoelectric materials and RFID technology to create efficient energy harvesting systems for mobile charging, aimed at supporting sustainable urban mobility.
  22. J. Zhou, Y. Lin, and H. Lee, “Design and Implementation of a Footstep Energy Harvesting System with RFID Access Control for Public Charging Stations,” 2021. This research introduces a prototype for a footstep energy harvesting system tailored for high-traffic locations, using RFID technology to ensure secure access to the generated energy.
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Footsteps, a ubiquitous source of mechanical energy, present a unique opportunity for sustainable power generation. With increasing mobile device dependency, this innovative approach addresses the challenge of eco-friendly energy solutions.Public spaces, especially high-footfall areas, provide an ideal setting for implementing such systems, benefiting users and reducing energy reliance. This study introduces a system that leverages piezoelectric sensors integrated into flooring to harvest energy from footsteps and convert it into electricity. The addition of RFID technology ensures that access to the stored energy is secure and authenticated for purposes like mobile charging. Notable features include effective energy conversion, real-time energy usage tracking, and secure access via RFID-based authentication. By utilizing renewable energy sources, the system aims to lower environmental impact and support sustainable practices in urban infrastructure.

Keywords : Footstep Power, RFID, Renewable Energy, Mobile Charging, Piezoelectric Sensors, Sustainable Energy, Eco-Friendly Solutions, Real-Time Monitoring.

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