Prediction of Surface Runoff Changes with Landuse-Land Cover Impact Using Remote Sensing Data and GIS Based ARcSWAT Model of Indrayani Watershed, Maharashtra, India

Authors

  • Narasayya Kamuju  Assistant Research Officer, CWPRS, Pune, Maharashtra, India

DOI:

https://doi.org//10.32628/CSEIT19564

Keywords:

Runoff, SWAT, GIS, HRU, DEM

Abstract

Modern Mathematical Models have been developed for studying the complex hydrological processes of a watershed and their direct relation to weather, topography, geology and land use. In this study the hydrology of Indrayani watershed located in Indrayani River basin at the North-East of Pune is modelled, using the Soil and water Assessment Tool (SWAT). It aims to simulate the surface runoff using a Temporal resolution of 10 years LandUse-LandCover (Lu-Lc) maps of 2003-04 and 2013-14. The ArcSWAT interface implemented in the ArcGIS software was used to delineate the study area and its sub-components, combine the data layers and edit the model database. The ArcSWAT model predicted Indrayani watershed hydrologic component of Surface Runoff with weather components of precipitation and temperature of 25 years along with Food and Agriculture Organisation soil layer. The SWAT model run in 2 Phases with Lu-Lc of 2003-04 as Phase-I and also model run using 2013-14 Lu-Lc as phase-II. The runoff predicted within a 10 year temporal changes of Lu-Lc, 919 mm of Surface Runoff obtained with Lu-Lc of 2003-04 and 767 mm of Surface Runoff predicted from 2013-14 Lu-Lc map layer respectively. The higher runoff predicted with Lu-Lc 2003-04, as such it has higher area of Agricultural land with lower urban area covered and less water bodies than 2013-14 Landuse-Lancover classes.

References

  1. V. P. Singh, D.K Frevert, Mathematical Modelling of Watersheds Hydrology. Chapter 1, in: Mathematical Models of Small Watershed Hydrology and Applications, Water Resources Publications, Littleton, Colorado, 2002,pp. 1-3.
  2. S.J. Bhuyan, J.K. Koelliker, L.J. Marzen, iJ.R. Harrington, An integrated approach for water quality assessment of kansa watershed, Environ. Model Softw.18 (2003) 473-484.
  3.  S.L.Neitsch, J.G.Arnold, J.R. Kiniry, J.R.Williams, Soil and Water Assessment Tools theoretical documentation version. GrassLand, Soil and Water Research Laboratory, Agricultural Research Service 808 East Blackland Road, Temple, Texas 76502; Blackland Research Centre, Texas Agricultural Experiment Station 720, East Blackland, Texas USA, 205.
  4. A.D.Khan, Shimaa M.Ghoraba, J.G. Arnold, Mauro DiLuzio, Hydrological modelling of Upper Indus basin and assessment of deltaic ecology, Int.J.Modern Eng.Res. 4 (1) (2004) 73-85, This paper indexed in ANED (American National Engineering Database). By ANED-DDL (Digital Data Link) number is 02.6645/IJMER-AJ317385
  5. Z.N. Asrin, G.A. Sayyad, S.E. Hosseini, Hydrological and sediment transport modeling in maroon dam catchment using soil and water assessment tool (SWAT), Int.J. Agron. PlantProd. 4 (10) (2013) 2791-2795.
  6. S Cindy, O. Koichiro, Dam construction impacts on streamflow and nutrient transport in kase River Basin, Int. J. CivilEnviron.Eng. IJCEE-IJENS 12 (13) (2012)
  7. A. Fadil, Hassan Rhianane, K. Abdelhadi, K. Youness, Omar A. Bachir, Hydrologic Modelling of the bouregreg watershed (Morocco) using GIS and SWAT model, J. Geogr. Inform.Syst. 3 (2011) 279 – 289.
  8. B.B. Ashagre, SWAT to Identify Watershed Management Options: Anjeni Watershed, Blue Nile Basin, Ethiopia, Master’s Thesis, Cornell University, New York, 2009.
  9. J. Schuol, K.C. Abbaspour, R. Srinivasan, H. Yang, Modeling Blue and green water availability in Africa at monthly interval sand sub basin level, Water resource. Res. 44 (2008) 1-18.
  10. Keiser& Associates for Environmental Science and Engineering, SWAT Modeling of the St. Joseph River Watershed, Michigan and Indian, Kieser & Associates Michigan Ave., Suite 300, Kalamazoo Michigan 49007, 2005.
  11. A.Shawul, T. Almirew, M.O. Dinka, Calibration and validation of SWAT model and estimation of water balance components of Shaya mountainous watershed , Southern Ethiopia, Hydrol. Earth Syst. Sci. Discuss 10 (2013) 13955-13978 , http://dx.doi.org/10.194/hessd-10-13955-2013.
  12. G.A. Adeniyi, F.S. Bolaji, W.S. Adebayo, O.D. Michael, Validation of SWAT model for prediction of water yield and water balance: case study of upstream catchment of Jebba Damin Nigeria, World Acad. Sci. Eng. Technol. Int.J.Phys.,Nucl.Sci.Eng.8(2) (2014) 57-63.
  13. J.G. Arnold, R. Srinivasan, R.S. Muttiah, J.R. Williams, Large area hydrologic modelling and assessment – Part1: Model development, J. Am. Water Resources. Assoc. 34 (1) (1998) 73-89.
  14. M. Winchell, R. Srinivasan, M. Di Luzio, J.G. Arnold, ArcSWAT 2.3.4 Interface for SWAT 2005: User's Guide, Version, September 2009, Texas Agricultural Experiment Station and Agricultural Research Service- US Department of Agriculture, Temple, 2009.
  15. CGIAR-CSI, The CGIAR Consortium for Spatial Informationhttp://srtm.csi.cgiar.org/SELECTION/inputCoord.asp (accessed 10.08.2019).
  16. Bhuvan-Indian Geo-platform of ISRO, https://bhuvan-app1.nrsc.gov.in/thematic/thematic/index.php (accessed 15.08.2019).
  17. FAO-AGL, United Nation Food and Agricultural Organization, 2003 http://www.fao.org/ag/agl/agll/wrb/soilres.stm#down (accessed 20.08.2019)
  18. NASA_POWER Data https://power.larc.nasa.gov/data-access-viewer/ (accessed 03.09.2019)

IInternational Journal of Scientific Research in Computer Science, Engineering and Information Technology

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Published

2019-11-30

Issue

Volume 5, Issue 6, November-December-2019

Section

Research Articles

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How to Cite

[1]
Narasayya Kamuju, " Prediction of Surface Runoff Changes with Landuse-Land Cover Impact Using Remote Sensing Data and GIS Based ARcSWAT Model of Indrayani Watershed, Maharashtra, India, IInternational Journal of Scientific Research in Computer Science, Engineering and Information Technology(IJSRCSEIT), ISSN : 2456-3307, Volume 5, Issue 6, pp.06-13, November-December-2019. Available at doi : https://doi.org/10.32628/CSEIT19564