Application of geospatial techniques for gravity-based drinking water supply management

Wawale, Surindar

doi:10.2478/apcrs-2019-0006

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Tytuł artykułu

Application of geospatial techniques for gravity-based drinking water supply management

Autorzy

Wawale Surindar

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DOI

10.2478/apcrs-2019-0006

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Języki publikacji

Abstrakty

There is growing interest in the research community to apply the various techniques pertaining to geospatial technology, with the advance part of Remote Sensing (RS) and Geographical Information System (GIS). This technology has been proven to be very essential in this identification and resolving the problem of water resource and allied water supply management. Considering the capabilities of geospatial techniques, the tools and techniques of similar disciplines used for gravity-based drinking water supply management in the hilly area where the human habitat is settled at foothill places. An attempt has been made in this paper to avail the use of tools and techniques of geospatial techniques for gravity-based water supply management at the village level. The Karule village is the part of central Maharashtra in India chosen for implementation of present bid. It was observed that, three-dimensional remote sensing data derived from space-borne satellite could be useful for gravity-based drinking water supply management with the help of other spatial and non-spatial database. Satellite-derived data and its incorporation with GIS and ground inventory data would be advantageous for delineation of such gravity-based water supply management in the similar area of world.

Słowa kluczowe

drinking water geospatial technology gravity-based water supply water management

woda pitna technologia geoprzestrzenna grawitacyjne zaopatrzenie w wodę gospodarka wodna

Wydawca

Zarząd Główny Stowarzyszenia Geodetów Polskich

Czasopismo

Archiwum Fotogrametrii, Kartografii i Teledetekcji

Rocznik

2019

Tom

vol. 31

Strony

75--83

Opis fizyczny

Bibliogr. 30 poz.

Twórcy

autor

Wawale Surindar

surendrawawale@gmail.com

Department of Geography, Agasti Arts, Commerce and Dadasaheb Rupwate Science College, Maharashtra, India

Bibliografia

1. Tadesse, A., Bosona, T, & Gebresenbet, G. (2013), Rural Water Supply Management and Sustainability: The Case of Adama Area, Ethiopia, Journal of Water Resource and Protection, 5, 208-221.
2. Boddu, M., Gaayam, T. & Annamdas, V.G.M., (2011), A Review on Inter basin Transfer of Water, Proceedings of 4th Int. Perspective on Water Resources & the Environment, National University of Singapore (NUS), Singapore.
3. Burrough, P. A. & McDonnell, R. A., (1998), Principles of geographic information systems, 333 pages (New York: Oxford University Press).
4. Cáñez-Cota, A. & Pineda-Pablos, N. (2019), Breaking Out of the Governance Trap in Rural Mexico, Water Alternatives, 12(!), 121-240.
5. Deshmukh K.K, & Aher S.P., (2016) Assessment of the impact of municipal solid waste on groundwater quality near the Sangamner City using GIS approach. Water resources management, 30, 2425-2443.
6. Dhanasekarapandian, M, Chandran, S, Devi, DS, & Kumar, V., (2016),Spatial and temporal variation of groundwater quality and its suitability for irrigation and drinking purpose using GIS and WQI in an urban fringe. Journal of African Earth Sciences 124, 270-288.
7. Garg, S. K. (2013), Water Supply Engineering, Khanna Publication, New Delhi.
8. Guth, P. L., (2010), Geomorphometric Comparison of ASTER GDEM and SRTM, A special joint symposium of ISPRS Technical Commission IV & AutoCarto in conjunction with ASPRS/CaGIS, Orlando, Florida.
9. Jiang, H., Feng, M., Zhu, Y., Lu., N., Huang, J. & Xiao, T., (2014). An Automated Method for Extracting Rivers and Lakes from Landsat Imagery, Remote Sensing, 6, 5067-5089.
10. John Magrath, (2006), Towards Sustainable Water-Supply Solutions in Rural Sierra Leone, Oxfam GB Research Report, pp 01-27.
11. Khan, M. A. (2002), Watershed management for sustainable agriculture, published by Agrobios (India) Jodhapur , pp. 13-19.
12. Kunlun Ding, (2019), State of Knowledge of Irrigation Techniques and Practicalities Within Given Socio-Economic Settings, Irrig. and Drain. 68, 31 –45.
13. Machell, J., S. R. Mounce, & J. B. Boxall, (2010) Online modelling of water distribution systems: a UK case study, Drink. Water Eng. Sci., 3, 21–27.
14. Miller, M. et al. (2019), External support programs to improve rural drinking water service sustainability: A systematic Review, Science ofthe Total Environment 670, 717–731. doi.org/10.1016/j.scitotenv.2019.03.069.
15. Neupane, J. & Guo, W., (2019), Agronomic Basis and Strategies for Precision Water Management: A Review, Agronomy 9, 87.
16. Newton, I., (1729), "In [experimental] philosophy particular propositions are inferred from the phenomena and afterwards rendered general by induction": "Principia", Book 3, General Scholium, at p.392 in Volume 2 of Andrew Motte's English translation published 1729.
17. Newton's law of universal gravitation- Wikipedia. Feb-2011, www.gisdevelopment.com, www.googleearth.com.
18. Nur Lely Hardianti Zendrato, Dhemi Harlan, Mohammad Bagus Adityawan, and Dantje Kardana Natakusumah., (2019), 1D Numerical modelling of dam break using finite element method, MATEC Web of Conferences 270, 04022
19. Ragade, G., Rajesh Dhumal, Bharti W. Gawali, (2018), Analysis and modelling of drinking water utilities by using GIS: in Aurangabad city, Maharashtra, India, Agronomy, Volume 6, Issue 1, pp 77–81
20. Rao N.S, Rao P.S, Reddy G.V, Nagamani M, Vidyasagar G, Satyanarayana N.,(2012), Chemical characteristics of groundwater and assessment of groundwater quality in Varaha River Basin, Visakhapatnam District, Andhra Pradesh, India. Environmental monitoring and assessment 184, 5189-5214.
21. Ritesh Patro, E., et al., (2018), Micro-hydropower in drinking water gravity pipelines: a case study in Uttarakhand, India, ISH Journal of Hydraulic Engineering,
22. Sainath Aher, Komali Kantamaneni, Pragati Deshmukh, (2017), Detection and Delineation of Water Bodies in Hilly Region using Carto DEM, SRTM and ASTER GDEM Data, Remote Sensing of Land, 1(1), 41-52.
23. Samantha Lee, (2018), Community-Based Water Management in Rural Kenya, Undergraduate Journal of Global Citizenship, 2(3), 01-18.
24. Raghav, S., Painuli/ R., & Dinesh ,K. (2019), Threats to Water: Issues and Challenges Related to Ground Water and Drinking Water, Springer International Publishing AG, part of Springer Nature, M. Naushad (ed.), A New Generation Material Graphene: Applications in Water Technology,
25. Singh, G, Bundela D, Sethi M, Lal K, Kamra S., (2010), Remote sensing and geographic information system for appraisal of salt-affected soils in India. Journal of environmental quality 39, 5-15.
26. Thomas M. Lillesand, (2009), Remote sensing and image Interpretation, Published by John Wiley & Sons (Asia) Pvt, ltd, Singapur, pp. 491-498.
27. Walker, J. P. and Willgoose, G. R., (1999), On the effect of digital elevation model accuracy on hydrology and geomorphology, Water Resources Research 35, 2259–2268.
28. Walski, Thomas M.; Chase, Donald V.; and Savic, Dragan A., (2001), Water Distribution Modeling, "Water Distribution Modeling" (2001).Civil and Environmental Engineering and Engineering Mechanics Faculty Publications. Paper 17.
29. Water harvesting brings ray of hope to Ahemadnagar by Sharad Mistry- Indian Express Newspapers (Bombay) Ltd.
30. Yue Xua, Xiao-yu, (2012), Zhangb Research on pressure optimization effect of high level water tank by drinking water network hydraulic model, Procedia Engineering 00 (2011) 000–000

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