TY - JOUR
T1 - Improvement of low flows simulation in the SASER hydrological modeling chain
AU - Cenobio-Cruz, Omar
AU - Quintana-Seguí, Pere
AU - Barella-Ortiz, Anaïs
AU - Zabaleta, Ane
AU - Garrote, Luis
AU - Clavera-Gispert, Roger
AU - Habets, Florence
AU - Beguería, Santiago
N1 - Funding Information:
This work was partially funded by the HUMID project (CGL2017-85687-R, AEI/FEDER, UE), the predoctoral grant PRE2018-085027 (AEI/FSE), the PIRAGUA project (EFA210/16-PIRAGUA, INTERREG V-A España-Francia-Andorra POCTEFA2014-2020) and the IDEWA project (PRIMA PCI2020-112043/AEI/ 10.13039/501100011033).
Publisher Copyright:
© 2022
PY - 2023/1/1
Y1 - 2023/1/1
N2 - The physically-based, spatially-distributed hydrometeorological model SASER, which is based on the SURFEX LSM, is used to model the hydrological cycle in several domains in Spain and southern France. In this study, the modeled streamflows are validated in a domain centered on the Pyrenees mountain range and which includes all the surrounding river basins, including the Ebro and the Adour-Garonne, with a spatial resolution of 2.5 km. Low flows were found to be poorly simulated by the model. We present an improvement of the SASER modeling chain, which introduces a conceptual reservoir, to enhance the representation of the slow component (drainage) in the hydrological response. The reservoir introduces two new empirical parameters. First, the parameters of the conceptual reservoir model were determined on a catchment-by-catchment basis, calibrating against daily observed data from 53 hydrological stations representing near-natural conditions (local calibration). The results show, on the median value, an improvement (ΔKGE of 0.11) with respect to the reference simulation. Furthermore, the relative bias of two low-flow indices were calculated and reported a clear improvement. Secondly, a regionalization approach was used, which links physiographic information with reservoir parameters through linear equations. A genetic algorithm was used to optimize the equation coefficients through the median daily KGE. Cross-validation was used to test the regionalization approach. The median KGE improved from 0.60 (default simulation) to 0.67 (ΔKGE = 0.07) after regionalization and execution of the routing scheme, and 79 % of independent catchments showed improvement. The model with regionalized parameters had a performance, in KGE terms, very close to that of the model with locally calibrated parameters. The key benefit if the regionalization is that allow us to determine the new empirical parameter of the conceptual reservoir in basins where calibration is not possible (ungauged or human-influenced basins).
AB - The physically-based, spatially-distributed hydrometeorological model SASER, which is based on the SURFEX LSM, is used to model the hydrological cycle in several domains in Spain and southern France. In this study, the modeled streamflows are validated in a domain centered on the Pyrenees mountain range and which includes all the surrounding river basins, including the Ebro and the Adour-Garonne, with a spatial resolution of 2.5 km. Low flows were found to be poorly simulated by the model. We present an improvement of the SASER modeling chain, which introduces a conceptual reservoir, to enhance the representation of the slow component (drainage) in the hydrological response. The reservoir introduces two new empirical parameters. First, the parameters of the conceptual reservoir model were determined on a catchment-by-catchment basis, calibrating against daily observed data from 53 hydrological stations representing near-natural conditions (local calibration). The results show, on the median value, an improvement (ΔKGE of 0.11) with respect to the reference simulation. Furthermore, the relative bias of two low-flow indices were calculated and reported a clear improvement. Secondly, a regionalization approach was used, which links physiographic information with reservoir parameters through linear equations. A genetic algorithm was used to optimize the equation coefficients through the median daily KGE. Cross-validation was used to test the regionalization approach. The median KGE improved from 0.60 (default simulation) to 0.67 (ΔKGE = 0.07) after regionalization and execution of the routing scheme, and 79 % of independent catchments showed improvement. The model with regionalized parameters had a performance, in KGE terms, very close to that of the model with locally calibrated parameters. The key benefit if the regionalization is that allow us to determine the new empirical parameter of the conceptual reservoir in basins where calibration is not possible (ungauged or human-influenced basins).
KW - Distributed modeling
KW - Genetic Algorithm
KW - Hydrology
KW - Land-Surface Model
KW - Low Flows
KW - Parameter Regionalization
UR - http://www.scopus.com/inward/record.url?scp=85144583537&partnerID=8YFLogxK
U2 - 10.1016/j.hydroa.2022.100147
DO - 10.1016/j.hydroa.2022.100147
M3 - Article
AN - SCOPUS:85144583537
SN - 2589-9155
VL - 18
JO - Journal of Hydrology X
JF - Journal of Hydrology X
M1 - 100147
ER -