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A Sustainable Forage-Grass-Power Fuel Cell Solution for Edge-Computing Wireless Sensing Processing in Agriculture 4.0 Applications

Author

Listed:
  • Johan J. Estrada-López

    (Faculty of Mathematics, Autonomous University of Yucatan, Mérida 97000, Mexico)

  • Javier Vázquez-Castillo

    (Informatics and Networking Department, Universidad Autónoma del Estado de Quintana Roo, Chetumal 77019, Mexico)

  • Andrea Castillo-Atoche

    (Chemistry and Biochemistry Department, Tecnológico Nacional de México/Instituto Tecnológico de Mérida, Mérida 97118, Mexico)

  • Edith Osorio-de-la-Rosa

    (Informatics and Networking Department, CONACYT-Universidad Autónoma del Estado de Quintana Roo, Chetumal 77019, Mexico)

  • Julio Heredia-Lozano

    (Mechatronics Department, Autonomous University of Yucatan, Mérida 97000, Mexico)

  • Alejandro Castillo-Atoche

    (Mechatronics Department, Autonomous University of Yucatan, Mérida 97000, Mexico)

Abstract

Intelligent sensing systems based on the edge-computing paradigm are essential for the implementation of Internet of Things (IoT) and Agriculture 4.0 applications. The development of edge-computing wireless sensing systems is required to improve the sensor’s accuracy in soil and data interpretation. Therefore, measuring and processing data at the edge, rather than sending it back to a data center or the cloud, is still an important issue in wireless sensor networks (WSNs). The challenge under this paradigm is to achieve a sustainable operation of the wireless sensing system powered with alternative renewable energy sources, such as plant microbial fuel cells (PMFCs). Consequently, the motivation of this study is to develop a sustainable forage-grass-power fuel cell solution to power an IoT Long-Range (LoRa) network for soil monitoring. The stenotaphrum secundatum grass plant is used as a microbial fuel cell proof of concept, implemented in a 0.015 m 3 -chamber with carbon plates as electrodes. The BQ25570 integrated circuit is employed to harvest the energy in a 4 F supercapacitor, which achieves a maximum generation capacity of 1.8 mW. The low-cost pH SEN0169 and the SHT10 temperature and humidity sensors are deployed to analyze the soil parameters. Following the edge-computing paradigm, the inverse problem methodology fused with a system identification solution is conducted, correcting the sensor errors due to non-linear hysteresis responses. An energy power management strategy is also programmed in the MSP430FR5994 microcontroller unit, achieving average power consumption of 1.51 mW, ∼19% less than the energy generated by the forage-grass-power fuel cell. Experimental results also demonstrate the energy sustainability capacity achieving a total of 18 consecutive transmissions with the LoRa network without the system’s shutting down.

Suggested Citation

  • Johan J. Estrada-López & Javier Vázquez-Castillo & Andrea Castillo-Atoche & Edith Osorio-de-la-Rosa & Julio Heredia-Lozano & Alejandro Castillo-Atoche, 2023. "A Sustainable Forage-Grass-Power Fuel Cell Solution for Edge-Computing Wireless Sensing Processing in Agriculture 4.0 Applications," Energies, MDPI, vol. 16(7), pages 1-17, March.
    • Handle: RePEc:gam:jeners:v:16:y:2023:i:7:p:2943-:d:1105346
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    References listed on IDEAS

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    1. Mohammad Nishat Akhtar & Abdurrahman Javid Shaikh & Ambareen Khan & Habib Awais & Elmi Abu Bakar & Abdul Rahim Othman, 2021. "Smart Sensing with Edge Computing in Precision Agriculture for Soil Assessment and Heavy Metal Monitoring: A Review," Agriculture, MDPI, vol. 11(6), pages 1-37, May.
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