Modelación hidrológica de una microcuenca Altoandina ubicada en el Austro Ecuatoriano

Raúl Fernando Vázquez Zambrano

doi:10.18537/mskn.01.01.06

Authors

Raúl Fernando Vázquez Zambrano Universidad de Cuenca https://orcid.org/0000-0003-2581-5372

DOI:

https://doi.org/10.18537/mskn.01.01.06

Keywords:

páramo, Andean region, numerical modeling, uncertainty, sensibility analysis, Monte Carlo simulations, GLUE

Abstract

Despite its importance, the hydrology of the Andean catchments is at the moment not well known. Hence, facing the continuously growing concern from society for a sustainable use of water resources and the conservation of mountain catchments of the Ecuadorian Austral region, it is relevant to start with research initiatives for getting to know, among other aspects, the interrelationships between climate and hydrology of páramos and the capacity of these ecosystems to “produce” water. In this context, the current manuscript describes some of the experiences modelling the hydrology of a micro-catchment located to the south-west of Cuenca (Ecuador), presenting some details of the model construction for the study site on the basis of a lumped conceptual code (NAM), as well as, some preliminary modelling results. The modelling protocol included a deterministic/stochastic approach based on Monte Carlo simulations. The initial modelling results are acceptable, which encourages the further improvement of the current version of the model, as well as, the further use of the numerical code on additional study sites such as Andean sub-catchments and catchments of interest.

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Allen, G.R., L.S. Pereira, D. Raes, S. Martin, 1998. Crop evapotranspiration-Guidelines for computing crop water requirements, FAO Irrigation and Drainage Paper 56. FAO, Roma, 300 págs.

Beven, K.J., 1993. Prophecy, reality and uncertainty in distributed hydrological modelling. Adv. Water Resour., 16, 41-51.

Beven, K.J., P. Smith, J. Freer, 2007. Comment on ‘‘Hydrological forecasting uncertainty assessment: Incoherence of the GLUE methodology’’ by Pietro Mantovan and Ezio Todini. J. Hydrol., 338 (3-4), 315-318.

Binley, A.M., K.J. Beven, A. Calver, L.G. Watts, 1991. Changing Responses in Hydrology: Assessing the Uncertainty in Physically Based Model Predictions. Water Resour. Res., 27(6), 1253-1261.

Braud, I., P. Fernandez, F. Bouraoui, 1999. Study of the rainfall-runoff process in the Andes region using a continuous distributed model. J. Hydrol., 216(3-4), 155-171.

Braud, I., A.I.J. Vich, J. Zuluaga, 2001. Vegetation influence on runoff and sediment yield in the Andes region: observation and modelling. J. Hydrol., 254(1-4), 124-144.

Buytaert, W., 2004. The properties of the soils of the south Ecuadorian páramo and the impact of land use changes on their hydrology. Tesis Ph.D., K.U.Leuven, Bélgica, 228 págs.

Buytaert, W., J. Deckers, G. Dercon, B. De Bièvre, J. Poesen, G. Govers, 2002. Impact of land use changes on the hydrological properties of volcanic ash soils in South Ecuador. Soil Use Manage., 18, 94-100.

Buytaert, W., B. De Bièvre, G. Wyseure, J. Deckers, 2004. The use of the linear reservoir concept to quantify the impact of land use changes on the hydrology of catchments in the Ecuadorian Andes. Hydrol. Earth Syst. Sc., 8, 108-114.

Buytaert, W., V. Iñegues, R. Célleri, B. De Bièvre, 2006. The impact of pine plantations on water yield: a case study from the Ecuadorian Andes. 3rd Internacional Symposium on Integrated Water Management, Bochum, Germany.

Célleri, R., J. Feyen, 2009. The hydrology of tropical Andean ecosystems. Mt. Res. Dev., 29, 350-355.

Célleri, R., L. Timbe, R.F. Vázquez, J. Feyen, 2003. Assessment of the relation between the NAM rainfall-runoff model parameters and the physical catchment properties. HIP-VI UNESCO Technical Documents in Hydrology, 66, 9-16.

DHI, 2000. MIKE 11 A Modelling System for Rivers and Channels. User Guide. Danish Hydraulic Institute, Dinamarca, 292 págs.

Fleischbein, K., W. Wilcke, R. Goller, J. Boy, C. Valarezo, W. Zech, K. Knoblich, 2005. Rainfall interception in a lower montane forest in Ecuador: effects of canopy properties. Hydrol. Process., 19 (7), 1355-1371.

Fleischbein, K., W. Wilcke, C. Valarezo, W. Zech, K. Knoblich, 2006. Water budgets of three small catchments under montane forest in Ecuador: experimental and modeling approach. Hydrol. Process., 20, 2491-2507.

Harden, C.P., C.P. Scruggs, 2003. Infiltration on mountain slopes: a comparison of three environments. Geomorphology, 55(1-4), 5-24.

Havnø, K., M.N. Madsen, J. Dørge, 1995. MIKE 11 A generalized modeling package. En: Singh, V.J. (Ed.): Computer Models of Watershed Hydrology. Water Resources Publications, EEUU, 809-846.

Mantovan, P., E. Todini, 2006. Hydrological forecasting uncertainty assessment: Incoherence of the GLUE methodology. J. Hydrol., 330, 368-381.

Legates, D.R., G.J. McCabe, 1999. Evaluating the use of 'goodness-of-fit' measures in hydrological and hydroclimatic model validation. Water Resour. Res., 35(1), 233-241.

Nash, J.E., J.V. Sutcliffe, 1970. River flow forecasting through conceptual models. Part I: A discussion of principles J. Hydrol., 10(3), 282-290.

Patiño, J.F., L.A. Montes, J.D. León, L.C. Hernández, 2006. Efecto de diferentes coberturas forestales sobre el rendimiento hídrico en una microcuenca de la Cordillera Central Colombiana. XXII Latin-American Congress of Hydraulics. Ciudad Guayana, Venezuela.

Perrin, J.L., C. Bouvier, J.L. Janeau, G. Menez, F. Cruz, 2001. Rainfall/runoff processes in a small peri-urban catchment in the Andes mountains. The Rumihurcu Quebrada, Quito (Ecuador). Hydrol. Process., 15(5), 843-854.

Poulenard, J., P. Podwojewski, J.L. Janeau, J. Collinet, 2001. Runoff and soil erosion under rainfall simulation of Andisols from the Ecuadorian Páramo: effect of tillage and burning. Catena, 45, 185-207.

Rankinen, K., T. Karvonen, D. Butterfield, 2006. An application of the GLUE methodology for estimating the parameters of the INCA-N model. Sci. Total Environ., 365(1-3), 123-139.

Refsgaard, J.C., 1997. Parameterisation, calibration and validation of distributed hydrological models. J. Hydrol., 198, 69-97.

Sánchez, P.E., Jr. S. Santiesteban, 2004. Perú. En: Hofstede, R., P. Segarra, P. Mena. (Eds). Los páramos del Mundo. Proyecto Atlas Mundial de los Páramos.Global Peatland Initiative/NC-IUCN/EcoCiencia, Quito, 159-203.

Vázquez, R.F., 2003. Assessment of the performance of physically based distributed codes simulating medium size hydrological systems. Tesis Ph.D. ISBN 90-5682-416-3, K.U.Leuven, Bélgica, 335 págs.

Vázquez, R.F., J. Feyen, 2003. Effect of potential evapotranspiration estimates on effective parameters and performance of the MIKE SHE-code applied to a medium-size catchment. J. Hydrol., 270, 309-327.

Vázquez, R.F., J. Feyen, 2008. Application of distributed hydrologic models. En: Pilar García-Navarro, P., E. Playán (Eds.): Numerical modelling of Hydrodynamics for Water Resources. Taylor & Francis, Londres, Reino Unido, 153-174.

Vázquez, R.F., L. Feyen, J. Feyen, J.C. Refsgaard, 2002. Effect of grid-size on effective parameters and model performance of the MIKE SHE code applied to a medium sized catchment. Hydrol. Process., 16(2), 355-372.

Vázquez, R.F., K. Beven, J. Feyen, 2009. GLUE based assessment on the overall predictions of a MIKE SHE application. Water Resour. Manag., 23(7), 1325-1349.

Zehetner, F., W.P. Miller, 2006. Erodibility and runoff-infiltration characteristics of volcanic ash soils along an altitudinal climosequence in the Ecuadorian Andes. Catena, 65(3), 201-213.

Hydrological modeling of a high-andean micro-basin located in the Ecuadorian Austro

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