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Wireless Personal Communications
Erschienen in: Wireless Personal Communications 2/2020

17.08.2020

Smart City Based Autonomous Water Quality Monitoring System Using WSN

verfasst von: Laiqa Binte Imran, Rana Muhammad Amir Latif, Muhammad Farhan, Hamza Aldabbas

Erschienen in: Wireless Personal Communications | Ausgabe 2/2020

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Abstract

WSN can be a tech in-full development with top-notch, outstanding foreseeable future. The utilization of wireless sensor network (WSN) to get a good quality observation is consists using some range of detector nodes having a network capacity which might be set up for productive effects or to get constant monitoring function. Water is critical within our own lives because of our wellbeing insurance and in different cases such as farming, marketplace, and for the animal’s presence. Diseases linked to inadequate sanitation and water states have over 200 million cases reported causing 5–10 million deaths throughout the world. Water tracking procedures are indispensable to restrain exactly the challenge is gently linked to inadequate household allocation, wasteful usage and too little decent. Wireless sensor networks also have gained fame over the study area only because they supply a promising infrastructure for both multiple monitoring and control software. For fixing the dilemma, various drinking water caliber processes were grown previously in the last ten years. The parameters included with the drinking water quality tracking would be the PH degree, turbidity, dissolved oxygen and temperature has been quantified at the true period from the detectors that ship the info into the bottom channel or control/monitoring space. This document suggests the way the tracking platform might be set up highlighting the elements of low-cost, simple setup, and effortless maintenance and handling. Using this radio platform for tracking purpose is not only going to lower the total observation procedure expenditure in the duration of centers installation and labor price tag but can even offer versatility in the duration of location or distance. In this paper, the essential layout and execution of WSN comprising Lora (wide area network) established technological innovation is suggested. The developed system is cheap and makes it possible for customization. A few preliminary links between dimension to rate the efficiency and efficiency of the machine can also be shown.
Vorheriger Artikel A Position Based Speed Adaptive Dissemination approach for Vehicular Ad hoc Networks

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Literatur
1.
Chen, Y., & Han, D. (2018). Water quality monitoring in smart city: A pilot project. Automation in Construction, 89, 307–316.CrossRef
2.
O’Flynn, B., et al. (2007). SmartCoast: a wireless sensor network for water quality monitoring. In: 32nd IEEE Conference on Local Computer Networks (LCN 2007), (pp. 815–816), IEEE.
3.
Adu-Manu, K. S., Tapparello, C., Heinzelman, W., Katsriku, F. A., & Abdulai, J.-D. (2017). Water quality monitoring using wireless sensor networks: Current trends and future research directions. ACM Transactions on Sensor Networks (TOSN), 13(1), 1–41.CrossRef
4.
Jin, J., Gubbi, J., Marusic, S., & Palaniswami, M. (2014). An information framework for creating a smart city through internet of things. IEEE Internet of Things Journal, 1(2), 112–121.CrossRef
5.
Noreen, U., Bounceur, A., & Clavier, L. (2017). A study of LoRa low power and wide area network technology. In: 2017 International Conference on Advanced Technologies for Signal and Image Processing (ATSIP), (pp. 1–6), IEEE.
6.
Gutierrez, J. A., Naeve, M., Callaway, E., Bourgeois, M., Mitter, V., & Heile, B. (2001). IEEE 802.15. 4: a developing standard for low-power low-cost wireless personal area networks. IEEE Network, 15(5), 12–19.CrossRef
7.
8.
Ullah, S., & Kwak, K. S. (2012). An ultra low-power and traffic-adaptive medium access control protocol for wireless body area network. Journal of medical systems, 36(3), 1021–1030.CrossRef
9.
Chen, S.-L., Lee, H.-Y., Chen, C.-A., Huang, H.-Y., & Luo, C.-H. (2009). Wireless body sensor network with adaptive low-power design for biometrics and healthcare applications. IEEE Systems Journal, 3(4), 398–409.CrossRef
10.
Ganesan, D., Krishnamachari, B., Woo, A., Culler, D., Estrin, D., & Wicker, S. (2002). Complex behavior at scale: An experimental study of low-power wireless sensor networks. Citeseer 2002.
11.
Bor, M. C., Roedig, U., Voigt, T., & Alonso, J. M. (2016). Do LoRa low-power wide-area networks scale?. In: Proceedings of the 19th ACM International Conference on Modeling, Analysis and Simulation of Wireless and Mobile Systems, pp. 59–67.
12.
Mukhopadhyay, S. C., & Mason, A. (2013). Smart sensors for real-time water quality monitoring. Berlin: Springer.CrossRef
13.
Pant, D., Van Bogaert, G., Diels, L., & Vanbroekhoven, K. J. B. T. (2010). “A review of the substrates used in microbial fuel cells (MFCs) for sustainable energy production. Bioresource Technology, 101(6), 1533–1543.CrossRef
14.
Davis, M. A., et al. (2014). A dietary-wide association study (DWAS) of environmental metal exposure in US children and adults. PLoS ONE, 9(9), e104768.CrossRef
15.
Ginebreda, A., & Prat, N. Experiences from surface water quality monitoring. Springer International Publishing, Berlin
16.
Schwarzenbach, R. P., et al. (2006). The challenge of micropollutants in aquatic systems. Science, 313(5790), 1072–1077.CrossRef
17.
Clara, M., Kreuzinger, N., Strenn, B., Gans, O., & Kroiss, H. J. W. R. (2005). The solids retention time—a suitable design parameter to evaluate the capacity of wastewater treatment plants to remove micropollutants. Water Research, 39(1), 97–106.CrossRef
18.
Ginebreda A., & Prat, N. Experiences from ground, coastal and transitional water quality monitoring. Springer International Publishing, Berlin
19.
Margot, J., et al. (2013). “Treatment of micropollutants in municipal wastewater: ozone or powdered activated carbon? Science of the Total Environment, 461, 480–498.CrossRef
20.
Zhou, J., Hong, H., Zhang, Z., Maskaoui, K., & Chen, W. J. W. R. (2000). “Multi-phase distribution of organic micropollutants in Xiamen Harbour China. Water Reasearch, 34(7), 2132–2150.CrossRef
21.
Talaie, A. J. P. (1997). “Conducting polymer based pH detector: A new outlook to pH sensing technology. Polymer, 38(5), 1145–1150.CrossRef
22.
Lim, H. (2003). Variations in the water quality of a small urban tropical catchment: Implications for load estimation and water quality monitoring. In B. Kronvang (Ed.), The Interactions between Sediments and Water. Developments in Hydrobiology (Vol. 169, pp. 57–63). Dordrecht: Springer. https://​doi.​org/​10.​1007/​978-94-017-3366-3_​10.CrossRef
23.
Huan, J., Li, H., Wu, F., & Cao, W. (2020). Design of water quality monitoring system for aquaculture ponds based on NB-IoT. Aquacultural Engineering, 90, 102088.CrossRef
24.
Etikasari, B., Kautsar, S., Riskiawan, H., & Setyohadi, D. (2020).Wireless sensor network development in unmanned aerial vehicle (uav) for water quality monitoring system. In: IOP Conference Series: Earth and Environmental Science, vol. 411, no. 1, p. 012061: IOP Publishing, Bristol.
25.
.Baronti, P., Barsocchi, P., Ferro, E., Mavilia, F., Piotto, M. & Strambini, L. (2020). Smart sensors in smart cities collaborate for indoor air quality. In: ELECTRIMACS 2019 (pp. 339–348). Springer, Berlin.
26.
Dalwadi, N. & Padole, M. (2020). The internet of things based water quality monitoring and control. In: Smart Systems and IoT: Innovations in Computing ( pp. 409–417). Springer, Berlin.
27.
Charef, A., Ghauch, A., Baussand, P., & MartinBouyer, M. J. M. (2000). Water quality monitoring using a smart sensing system. Measurement, 28(3), 219–224.
28.
Barabde, M., & Danve, C. (2015). Real time water quality monitoring system. International Journal of Innovative Research in Computer and Communication Engineering, 3(6), 5064–5069.CrossRef
Metadaten
Titel
Smart City Based Autonomous Water Quality Monitoring System Using WSN
verfasst von
Laiqa Binte Imran
Rana Muhammad Amir Latif
Muhammad Farhan
Hamza Aldabbas
Publikationsdatum
17.08.2020
Verlag
Springer US
Erschienen in
Wireless Personal Communications / Ausgabe 2/2020
Print ISSN: 0929-6212
Elektronische ISSN: 1572-834X
DOI
https://doi.org/10.1007/s11277-020-07655-x

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