Abstract
Remote sensing (RS) and Geographic Information System (GIS) are potential tools for competent planning and administration of essential groundwater resources. In this study, a typical methodology is proposed to delineate groundwater target zones using integrated RS, GIS and Analytical Hierarchy Process (AHP) method. The developed methodology is confirmed by a case study in Karur district of Tamil Nadu, Southern India. Seven thematic layers, viz., Lithology, Lineament Density, Geomorphology, Slope, Post– Monsoon Water Level, Drainage Density and Landuse/Land cover were considered in this study. Selected seven thematic layers and their features were assigned suitable weights on the Saaty’s scale according to their virtual significance in groundwater incidence. The assigned weights of the thematic layers and their features were then normalized by using AHP. Finally, the selected seven thematic maps were incorporated by weighted linear combination method in a GIS environment to produce a groundwater targeting map. Thus, five groundwater targeting zones were identified and demarcated in the study area, viz., ‘very good’, ‘good’, ‘moderate’, ‘poor’ and ‘very poor’. The groundwater targeting map was finally verified using the well discharge data and the result was found acceptable. The ultimate result depicts the favorable groundwater targeting zones in the study area and can be helpful in better planning and managing of groundwater resources particularly in hard rock terrains.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Anbazhagan S, Aschenbrenner F, Knoblich K (2001) Comparison of aquifer parameters with lineaments derived from remotely sensed data in Kinzig basin, Germany. XXXI. IAH congress: New approaches to characterising groundwater flow, Munich, 10–14 September, Vol. 2, pp. 883–886
Bahuguna IM, Nayak S, Tamilarasan V, Moses J (2003) Groundwater prospective zones in basaltic terrain using remote sensing. J Indian Soc Remote Sens 31(2):107–118
CGWB (2008) District groundwater brochure, karur district, Tamil Nadu. CGWB, Ministry of Water Resources, Faridabad, pp. 1–23
Charon JE (1974) Hydrogeological applications of ERTS satellite imagery. In: Proc UN/FAO regional seminar on remote sensing of earth resources and environment. CommonwSciCounc, Cairo, pp. 439–456
Choudhury PR (1999). Integrated remote sensing and GIS techniques for groundwater studies in part of Betwa basin. Ph.D. Thesis (unpublished). Department of Earth Sciences, University of Roorkee
Chowdhury A, Jha MK, Chowdary VM, Mal BC (2009) Integrated remote sensing and GIS-based approach for assessing groundwater potential in West Medinipur district, West Bengal, India. Int J Remote Sens 30(1):231–250
Edet AE, Okereke CS, Teme SC, Esu EO (1998) Application of remote sensing data to groundwater exploration: A case study of the cross-river state, South eastern Nigeria. Hydrogeol J 6:394–404
El-Baz F, Himida I, Kusky T, Fielding L (1995) Groundwater potential of the Sinai Peninsula, Egypt. United States Agency for International Development, Cairo
El-Shazly EM, El-Raikaiby NM, El-Kassas IA (1983) Groundwater investigation of WadiAraba area, eastern desert of Egypt, using landsat imagery. Proceedings of the 17th Symposium on Remote Sensing of the Environment, Michigan 9(13):003–1013
Harinarayana P, Gopalakrishna GS, Balasubramanaian A (2000) Remote sensing data for groundwater development and management in Keralapura watersheds of Cauvery basin, Karnataka, India. Indian Miner 34(2):11–17
Jagadeeswara Rao P, Harikrishna P, Suryaprakasa Rao B (2004) An integrated study on groundwater resource of PeddaGedda watershed. J IndSoc Remote Sens 18(1&2):9–14
Jayakumar R, Ramasamy, SM (1996) Groundwater targeting in hard rock terrain through geomorphic mapping: a case study in part of South India. Asian Pac Remote Sens GIS J, Vol. 8, No. 2, pp. 17-23
Jha MK, Chowdary VM, Chowdhury A (2010) Groundwater assessment in Salboni Block, West Bengal (India) using remote sensing, geographical information system and multi-criteria decision analysis techniques. Hydrogeol J 18(7):1713–1728
Kamal K, Hamid RN (2011) Groundwater exploration using remote sensing and geographic information systems in a semi-arid area (Southwest of Urmieh, Northwest of Iran). Arab J Geosci. doi:10.1007/s12517-011-0414-4
Kukillaya JP, Padmanbhan K, Krishnan E (1999) Use and limitations of short and medium duration pumping tests in understanding hard rock aquifers—an example from Kerala. J Geol Soc India 54:267–277
Kumanan CJ, Ramasamy SM (2003) Fractures and the transmissivity behavior of the hard rock aquifer systems in parts of Western Ghats, Tamil Nadu, India. Escap Water Resour J Bangkok (June):53–59
Kumanan CJ, Ramasamy SM, Palanivel K (2000) A new Genetic GIS Based Groundwater Targetting in Theni, Madurai, Dindigul Districts of Tamil Nadu, India. State Conf. on Groundwater exploration Techniques, 30-31, March, National College, Tiruchirappalli. pp. 270-271
Mabee SB, Hardcastle KC, Wise DU (1994) A method of collecting and analyzing lineaments for regional scale fractured bedrock aquifer studies. Ground Water 32:884–894
Madrucci V, Taioli F, de Araújo CC (2008) Groundwater favorability map using GIS multicriteria data analysis on crystalline terrain, São Paulo State, Brazil. J Hydrol 357:153–173
Nag SK (2005) Application of lineament density and hydrogeomorphology to delineate groundwater potential zones of Baghmundi block in Purulia district, West Bengal, J Indian Soc Remote Sens, Vol. 33, No. 4, pp. 521–529
Nag SK, Anindita L (2011) Integrated approach using Remote Sensing and GIS techniques for delineating groundwater potential zones in Dwarakeswar watershed, Bankuradistict, West Bengal, International. J Geomatics Geosci 2(2):430–442
Nag SK, Ghosh P (2012) Delineation of groundwater potential zone in Chhatna Block, Bankura District, West Bengal, India using remote sensing and GIS techniques. Environ Earth Sci:1–13. doi:10.1007/s12665-012-1713-0
Palanivel K (2000) Remote sensing and GIS in water resources prospecting and conservation—parts of Western Ghats, Tamil Nadu, India. Ph.D. Thesis, Bharathidasan University, Tiruchirappalli
Palanivel K, Ramasamy SM (2001) Folded structures and groundwater Flow in Hard rock Aquifer Systems in parts of Western ghats, Tamil Nadu, India - IGC - 2002, Feb. 20-22 2002, International Groundwater Conference on “Sustainable Development and Management of Goundwater Resources in Semi-Arid Region with special reference to hard rocks”, (Ed. M. Thangarajan, S.N.Rai and V.S. Singh):pp.74-75
Pandian M, Kumanan CJ (2013) Geomatics approach to demarcate groundwater potential zones using remote sensing and GIS techniques in part of Trichy and Karur district, Tamilnadu, India. Arch Appl Sci Res 2013 5(2):. 234–. 240
Pereira JM, Uckstein L (1993) A multiple criteria decision-making approach to GIS-based land suitability evaluation. Int J Geogr Inf Syst 7(5):407–424
Preeja KR, Sabu J, Jobin T, Vijith H (2011) Identification of groundwater potential zones of a tropical river basin (Kerala, India) using remote sensing and GIS techniques. J Indian Soc Remote Sens 39(1):83–94. doi:10.1007/s12524-011-0075-5
Ramasamy SM, Bakliwal PC (1983) Groundwater Targeting of Banded Gneissic Complex, Rajasthan, Through Remote Sensing. Proc. Nat. Sem. Rem. Sen. in Development and Management of Water Resources, Space Application Centre, Ahmedabad, India. pp 277–285
Ramasamy SM, Thillaigovindarajan S, Balasubramanian T (1989) Remote sensing based appropriate methodology for groundwater exploration—A case study. In: Gupta CP (ed) Precambrians of South India. proceeding of IGW 89, NGRI. Oxford Press, pp. 327–332
Saaty TL (1977) A scaling method for priorities in hierarchical structures. J Math Psychol 15:234–281
Saaty TL (1980) The analytic hierarchy process: planning, priority setting, resource allocation. McGraw-Hill, New York, p. 287
Saaty TL (1994) How to make a decision: the analytical hierarchy process. Interfaces 24(6):19–43
Saaty TL (2005) Theory and applications of the theory of the analytic network processes. Decision making with benefits, opportunities, costs, and risks. RWS Publications, Pittsburgh
Saaty TL, Vargas LG (1991) Prediction, projection and forecasting. Kluwer Academic Publishers, Dordrecht, p. 251
Saro L, Kyo-Young S, Yongsung K, Park I (2012) Regional groundwater productivity potential mapping using a geographic information system (GIS) based artificial neural network model. Hydrogeol J 20(8):1511–1527. doi:10.1007/s10040-012-0894-7
Sener E, Davraz A, Ozcelik M (2005) An integration of GIS and remote sensing in groundwater investigations: a case study in Burdur, Turkey. Hydrogeol J 13:826–834
Shahid S, Nath SK (2002) GIS integration of remote sensing and electrical sounding data for hydrogeological exploration. J Spat Hydrol 2(1), pp. 1–10
Subba Rao N, Prathap Reddy (1999) Groundwater prospects in a developing satellite township of Andhra Pradesh, India. J Indian Soc Remote Sens 27(4):193–203
Subba Rao N, Chakradhar GKJ, Srinivas V (2001) Identification of groundwater potential using remote sensing techniques in and around Guntar town, Andhra pradesh, India. J Indian Soc Remote Sens 29(1 & 2):69–78
Acknowledgments
Authors wish to thank Prof.S.M.Ramasamy, DST- Chair Professor and Prof.C.J. Kumanan, Emeritus Professor, Center for Remote Sensing, Bharathidasan University, Tiruchirappalli, India for their constant encouragement to carry out this research work. And further authors thank the Chief Editor of the journal and the reviewers of this paper.
Author information
Authors and Affiliations
Corresponding author
Additional information
Communicated by: H. A. Babaie
Rights and permissions
About this article
Cite this article
Muralitharan, J., Palanivel, K. Groundwater targeting using remote sensing, geographical information system and analytical hierarchy process method in hard rock aquifer system, Karur district, Tamil Nadu, India. Earth Sci Inform 8, 827–842 (2015). https://doi.org/10.1007/s12145-015-0213-7
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s12145-015-0213-7