Environment and Water Engineering

Current Issue

By Issue

By Author

By Subject

Author Index

Keyword Index

About Journal

Aims and Scope

Editorial Board

Indexing and Abstracting

Journal Metrics

Peer Review Process

FAQ

Related Links

News

Paper Format

Forms and Format Template

Publication Fee

How to use journal site

Publication Ethics

Open Access Policy

Self-Archiving Policy

Comparison and Assessment of Two Lumped AWBM and Semi-Distributed SWAT Models in Monthly Runoff Simulation of Gharah-Sou River in Kermanashah Province, Iran

Document Type : Research Paper

Authors

1 Assisst. Prof., Department of Civil Engineering (Water Resources Management and Engineering), Knowledge Development Non-profit Higher Education Institute, Sanandaj, Iran

2 Professor, Department of Hydrology and Water Resources, Soil Conservation and Watershed Management Research Institute (SCWMRI), Tehran, Iran

Abstract

In recent years determination of different components of water balance has been the focus of many hydrological modeling techniques. In most basins, it is not feasible to measure all the different quantities for a detailed and enhanced hydrological modeling. Therefore, it is necessary to select a model capable of simulating hydrological events with the least number of variables; while being simple to use. Hence, in this paper the monthly runoff of Ravansar Sanjabi basin, Kermanshah, Iran was simulated through AWBM and SWAT models. AWBM is a lumped model simulating the runoff in basins using rainfall and evaporation variables. On the other hand, SWAT model is a continuous and semi-distributive model, which can simulate the hydrological processes in basins through a wide range of information such as physical information of basins (soil, land use, slope) as well as weather data such as precipitation, temperature, wind, relative humidity, and solar radiation. Simulation results during the calibration and validation periods were evaluated through two statistical indices: Nash–Sutcliffe efficiency (NSE) and coefficient of determination, R2. Comparison of calculated statistical coefficients showed that SWAT model has better results in simulating monthly runoff in calibration and validation periods so that the calculated NSEcoefficient was equal to 0.7 and 0.81 respectively and 0.63 and 0.5 for AWBM model respectively.

Keywords

Main Subjects

References
Abbaspour K. C., Johnson A.C. and Van Genuchten T. H. M. (2004). Estimating uncertain flow and transport parameters using a sequential uncertainty fitting procedure. Vadose Zone J., 3, 1340–1352.
 
Abbaspour K. C., Yang J., Maximov I., Siber R., Bogner K., Mieleitner J., Zobrist J. and Srinivasan R. (2007). Modelling hydrology and water quality in the pre-alpine/alpine Thur watershed using SWAT. J. Hydrol., 333, 413-430.
 
Behmanesh J., Jabari A., Montaseri M. and Rezaei H. (2014). Comparing AWBM and SimHyd models in rainfall-runoff modeling (Case study: Nazlou Chay catchment in west Azarbijan). Geogr. Environ. Plan., 52(4), 155–168 [In Persian].
 
Boughton, W. C. (1993). A hydrograph-based model for estimating the water yield of ungauged catchments. In: Proceedings of the 1993 Hydrology and Water Resources Symposium, Institution of Engineers, Australia, National Conference Publication, 93(14), 317–324.
 
Boughton W. (2009). A new approach to calibration of the AWBM for use on ungauged catchments. J. Hydrol. Eng., 14, 562–574.
 
Goodarzi M., Zahabioun B., Mesah Bowani A. and Kamal A. (2013). Evaluation of three SWAT, IHACRAS, and Hydrological models in runoff simulation in Ghareh Sou Basin. J. Water Drain. Manag., 1, 25–40 [In Persian].
 
Hosseini M. (2011). Effect of Landuse Changes on Surface runoffand Suspended Sediment Yield of Taleghan Catchment, Iran.  PhD Thesis, UPM University, Serdang, Malaysia, 210 pp.
 
Hosseini M. (2014). Water balance simulation of Garahsou basin of Kermanshah province by using SWAT model. J. Watershed Eng.Manag., 6, 63–73 [In Persian].
 
Hosseini M. and Ashraf M.A. (2015). Application of the SWAT Model for Water Components Separation in Iran. Springer, 97–98.
 
Hosseini M., Ghafouri M., Tabatabaei M., Goodarzi M. and Mokarian Z. (2016). Estimating hydrologic budgets for six Persian Gulf watersheds, Iran. Appl. Water Sci., 7, 1–10.
 
Kult J., Choi W. and Choi J. (2014). Sensitivity of the Snowmelt Runoff model to snow covered area and temperature inputs. Appl. Geogr., 55, 30–38.
 
Lang J., Schick A.P. and Leibundgut C. (1999). A noncalibrated rainfall-runoff model for large, arid catchments. Water Resour. Res., 35(7), 2126–2177.
 
Li L., Lambert M.F., Holger R.M., Partington D. and Simmons C.T. (2015). Assessment of the internal dynamics of the Australian Water Balance Model under different calibration regimes. Environ. Model. Software., 66, 57–68.
 
Oeurng C., Sauvage S. and Sanchez-Perez J. M. (2011). Assessment of hydrology, sediment and particulate organic carbon yield in a large agricultural catchment using the SWAT model. J. Hydrol., 401, 145–153.
 
Podger G. (2004). RRL rainfall runoff library users guide. Cooperative Research Centre for Catchment Hydrology. Available from http://www.toolkit.net.au.
 
Romanowici A. A., Vanclooster M., Rounsevell M. and La junesse I. (2005). Sensitivity of the SWAT model to the soil and land use data parameterization. A case study in the Thyle catchment, Belgium. Ecol. Model., 187, 27–39.
 
Rostamian R., Jaleh A., Afyuni M., Mousavi S. F., Heidarpour M., Jalalian A. and Abbaspour K. C. (2008). Application of a SWAT model for estimating runoff and sediment in two mountainous basins in central Iran. J. Hydrol., 53, 977–988.
 
Sommerlot A., Nejadhashemi A., Woznicki S., Giri S. and Prohaska M. (2013). Evaluating the capabilities of watershed-scale models in estimating sediment yield at field-scale. J. Environ. Manag., 127, 227-236.
 
Tahmasebi R., Sharifi F., Kaveh F. and Tavassoli A. (2010). Designing of rainwater collecting systems in micro catchment by using AWBM Model for cultivating of forage maize SC704. J. Range Watershed Manag., 63(3), 359–373 [In Persian].
 
Zarin H., Moghaddamnia A. R., Nam Dorost J. and Mosaedi A. (2013). Simulation of outlet runoff in       ungauged catchments by using AWBM Rainfall-Runoff Model. J. Water Soil Conserv., 20(2), 195–208 [In Persian].
Environment and Water Engineering
Volume 5, Issue 1
May 2019
Pages 71-82
Files
History
  • Receive Date: 06 August 2018
  • Revise Date: 26 April 2019
  • Accept Date: 15 May 2019
Share
How to cite
Statistics