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Green IoT: how wireless sensor networks are paving the way for sustainable smart environments

Document Type : Original Article

Author

Analytic in the Digital Era, Collage of Business and Economic, United Arab Emirates University, United Arab Emirates.

Abstract

The Internet of Things (IoTs) enables the incorporation and connecting of physical devices to the internet with little human intervention and human-to-human or human-to-PC communication. It discusses the future pattern and the next major upheaval unfolding in the realm of information technology. Individuals and objects are linked to everything and anybody, anytime, wherever, and via the use of organization or administration. It also focuses on how IoT can promote a greener and cleaner environment through Green Internet of Things (G-IoT). This article provides an overview of IoT and G-IoT. It also covers various advancements and problems in G-IoT and how it might reduce energy use. This article clarifies the concept of the IoT, including its features, security concerns, and technology adoption trends.

Keywords

References
[1]     Bhat, R., & Pavithra, K. N. (2023). Toward secure fault-tolerant wireless sensor communication: challenges and applications. Intelligent communication technologies and virtual mobile networks, 177–188. https://link.springer.com/chapter/10.1007/978-981-99-1767-9_14
[2]     Qu, Z., Xu, H., Zhao, X., Tang, H., Wang, J., & Li, B. (2022). A fault-tolerant sensor scheduling approach for target tracking in wireless sensor networks. Alexandria engineering journal, 61(12), 13001–13010.
[3]     Mohapatra, H., & Rath, A. K. (2019). Detection and avoidance of water loss through municipality taps in India by using smart taps and ICT. IET wireless sensor systems, 9(6), 447–457.
[4]     Shukla, R., Kumar, A., & Niranjan, V. (2022). A survey: faults, fault-tolerance & fault detection techniques in wsn [presentation]. 2022 5th international conference on contemporary computing and informatics (IC3I) (pp. 1761–1766). https://ieeexplore.ieee.org/abstract/document/10072611/
[5]     Rajeshwari, K. S., & Devi, K. A. S. (2023). Fault tolerance and energy efficient multi-Hop clustering with dual base stations in large scale wireless sensor network. SN computer science, 4(3), 309. https://link.springer.com/article/10.1007/s42979-023-01745-w
[6]     Vladislav, D. S. (2022). A short study on smart water distribution through sensor network. Big data and computing visions, 2(3), 122–127.
[7]     Mohapatra, H., & Rath, A. K. (2022). IoE based framework for smart agriculture: networking among all agricultural attributes. Journal of ambient intelligence and humanized computing, 13(1), 407–424.
[8]     Shyama, M., Pillai, A. S., & Anpalagan, A. (2022). Self-healing and optimal fault tolerant routing in wireless sensor networks using genetical swarm optimization. Computer networks, 217, 109359. https://doi.org/10.1016/j.comnet.2022.109359
[9]     Achour, M., & Boufaied, A. (2023). Check for updates multi-objective optimization for sensor networks based smart parking systems. Intelligent systems design and applications: 22nd international conference on intelligent systems design and applications (ISDA 2022) (Vol. 646, p. 230). Springer Nature.
[10]   Vishal Sharad, H., Desai, S. R., & Krishnrao, K. Y. (2022). Fault-tolerant multi-path data communication mechanism in WSN Based on optimization enabled routing. Wireless personal communications, 125(1), 841–859. DOI: 10.1007/s11277-022-09580-7
[11]   Yadav, A., Noori, M. T., Biswas, A., & Min, B. (2023). A concise review on the recent developments in the internet of things (IoT)-based smart aquaculture practices. Reviews in fisheries science & aquaculture, 31(1), 103–118.
[12]   Kyakulumbye, S., & Pather, S. (2022). Digital and big data initiatives for smart cities in developing countries: a socio-technical view for developing city contexts. Future of information and communication conference (pp. 53–73). Cham: Springer International Publishing.
[13]   Mohapatra, H. (2020). Offline drone instrumentalized ambulance for emergency situations. IAES international journal of robotics and automation, 9(4), 251. https://www.academia.edu/download/67300537/20298_37845_2_PB.pdf
[14]   Nadeem, M. F., Imran, M., Afzal Siddiqui, H. M., & Azeem, M. (2023). Fault tolerance designs of interconnection networks. Peer-to-peer networking and applications, 16(2), 1125–1134.
[15]   Mohapatra, H., & Rath, A. K. (2020). Social distancing alarming through proximity sensors for COVID-19 (No. 18). https://wvvw.easychair.org/publications/preprint_download/dMGk
[16]   Bhat, A. W., & Passi, A. (2022). Wireless sensor network motes: a comparative study. 2022 9th international conference on computing for sustainable global development (indicator) (pp. 141–144). IEEE.
[17]   Mohapatra, H., & Rath, A. K. (2020). Smart bike wheel lock for public parking. Application number, 1(3), 126–129. DOI: 10.22105/cand.2022.161804
[18]   Muniz, R. D. F., Almaz Ali Yousif, B., & Shemshad, A. (2022). River water quality monitoring through IoT enabled technologies. Computational algorithms and numerical dimensions, 1(1), 35–39.
[19]   Wang, M. (2022). Forest fire detection using wireless sensors and networks. Big data and computing visions, 2(3), 107–111. DOI: 10.22105/bdcv.2022.332453.1060
[20]   Obaideen, K., Yousef, B. A. A., AlMallahi, M. N., Tan, Y. C., Mahmoud, M., Jaber, H., & Ramadan, M. (2022). An overview of smart irrigation systems using IoT. Energy nexus, 1–11. DOI: 10.1016/j.nexus.2022.100124
Big Data and Computing Visions
Volume 3, Issue 2
June 2023
Pages 39-44
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History
  • Receive Date: 23 November 2022
  • Revise Date: 18 January 2023
  • Accept Date: 13 February 2023
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