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Energizing wireless sensor networks by energy harvesting systems: Scopes, challenges and approaches

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  • Zahid Kausar, A.S.M.
  • Reza, Ahmed Wasif
  • Saleh, Mashad Uddin
  • Ramiah, Harikrishnan

Abstract

As the wireless sensor networks (WSNs) technology has great advancement, small and smart WSN systems now can be used for more complicated and challenging applications. WSNs investigation has primarily believed the use of a convenient and inadequate energy source for empowering the sensors. A sensor becomes useless in the absence of energy and becomes unable to contribute to the utility of the network as a group. Therefore, extensive efforts have been used in finding energy-efficient networking protocols for increasing the life span of WSNs. However, there are promising WSN applications where the sensors are obligatory to work for a long time after their deployments. In these cases, batteries are tough or impractical to replace/recharge. Although, a little amount of power is required for these applications, the useable lifetime of WSNs is decreased by the gradual degradation of the batteries. With the motivation of raising the usable WSNs around us and to value a number of economic and environmental limitations, researchers are looking for new green and theoretically unlimited energy sources. Harvesting of energy from the ambient energy is the basement of these new sources. Energy harvesting devices efficiently and effectively capture, accumulate, store, condition, and manage this energy and supply it in a form that can be used to empower WSNs. This harvested energy can be an alternative energy source for adding-on a principal power source and thus increase the consistency of the whole WSN by preventing the disruption of power. A great deal of research has been reviewed and specific ranges of applications have been found. Though there are challenges to overcome, different researchers have taken different approaches to solve those. In this review, we have emphasized on different scopes, challenges, ideas and actions of energy harvesting for WSNs.

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  • Zahid Kausar, A.S.M. & Reza, Ahmed Wasif & Saleh, Mashad Uddin & Ramiah, Harikrishnan, 2014. "Energizing wireless sensor networks by energy harvesting systems: Scopes, challenges and approaches," Renewable and Sustainable Energy Reviews, Elsevier, vol. 38(C), pages 973-989.
    • Handle: RePEc:eee:rensus:v:38:y:2014:i:c:p:973-989
    DOI: 10.1016/j.rser.2014.07.035
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    4. Eteng, Akaa Agbaeze & Rahim, Sharul Kamal Abdul & Leow, Chee Yen & Jayaprakasam, Suhanya & Chew, Beng Wah, 2017. "Low-power near-field magnetic wireless energy transfer links: A review of architectures and design approaches," Renewable and Sustainable Energy Reviews, Elsevier, vol. 77(C), pages 486-505.
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    6. Islam, Nazrul & Marinakis, Yorgos & Majadillas, Mary Anne & Fink, Matthias & Walsh, Steven T., 2020. "Here there be dragons, a pre-roadmap construct for IoT service infrastructure," Technological Forecasting and Social Change, Elsevier, vol. 155(C).
    7. Sahraei, Nasim & Looney, Erin E. & Watson, Sterling M. & Peters, Ian Marius & Buonassisi, Tonio, 2018. "Adaptive power consumption improves the reliability of solar-powered devices for internet of things," Applied Energy, Elsevier, vol. 224(C), pages 322-329.
    8. Eswaran, U. & Ramiah, H. & Kanesan, J. & Reza, A.W., 2015. "Energy saving power amplifier design methodologies for mobile wireless communications," Renewable and Sustainable Energy Reviews, Elsevier, vol. 51(C), pages 1721-1727.
    9. Cha, Youngsu & Chae, Woojin & Kim, Hubert & Walcott, Horace & Peterson, Sean D. & Porfiri, Maurizio, 2016. "Energy harvesting from a piezoelectric biomimetic fish tail," Renewable Energy, Elsevier, vol. 86(C), pages 449-458.
    10. Kan, Junwu & Fu, Jiawei & Wang, Shuyun & Zhang, Zhonghua & Chen, Song & Yang, Can, 2017. "Study on a piezo-disk energy harvester excited by rotary magnets," Energy, Elsevier, vol. 122(C), pages 62-69.
    11. Gerald K Ijemaru & Kenneth Li-Minn Ang & Jasmine KP Seng, 2022. "Wireless power transfer and energy harvesting in distributed sensor networks: Survey, opportunities, and challenges," International Journal of Distributed Sensor Networks, , vol. 18(3), pages 15501477211, March.
    12. Latif, Usman & Younis, M. Yamin & Idrees, Saad & Uddin, Emad & Abdelkefi, Abdessattar & Munir, Adnan & Zhao, Ming, 2023. "Synergistic analysis of wake effect of two cylinders on energy harvesting characteristics of piezoelectric flag," Renewable and Sustainable Energy Reviews, Elsevier, vol. 173(C).
    13. Dominic Samoita & Charles Nzila & Poul Alberg Østergaard & Arne Remmen, 2020. "Barriers and Solutions for Increasing the Integration of Solar Photovoltaic in Kenya’s Electricity Mix," Energies, MDPI, vol. 13(20), pages 1-17, October.
    14. Wang, Quan & Kim, Kyung-Bum & Woo, Sang Bum & Ko, Sung Min & Song, Yooseob & Sung, Tae Hyun, 2022. "Enhanced electrical performance of spring-supported magneto piezoelectric harvester to achieve 60 Hz under AC magnetic field," Energy, Elsevier, vol. 238(PB).
    15. Wei, Chongfeng & Jing, Xingjian, 2017. "A comprehensive review on vibration energy harvesting: Modelling and realization," Renewable and Sustainable Energy Reviews, Elsevier, vol. 74(C), pages 1-18.
    16. Quan Wang & Kyung-Bum Kim & Sang-Bum Woo & Yooseob Song & Tae-Hyun Sung, 2021. "A Magneto-Mechanical Piezoelectric Energy Harvester Designed to Scavenge AC Magnetic Field from Thermal Power Plant with Power-Line Cables," Energies, MDPI, vol. 14(9), pages 1-12, April.
    17. M׳boungui, G. & Adendorff, K. & Naidoo, R. & Jimoh, A.A. & Okojie, D.E., 2015. "A hybrid piezoelectric micro-power generator for use in low power applications," Renewable and Sustainable Energy Reviews, Elsevier, vol. 49(C), pages 1136-1144.

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