Calibration approaches for distributed hydrologic models in poorly gaged basins: Implication for streamflow projections under climate change(Article)(Open Access)
- aDepartment of Civil and Environmental Engineering, University of Massachusetts, Amherst, MA, United States
- bWorld Bank, Washington, DC, United States
Abstract
This study tests the performance and uncertainty of calibration strategies for a spatially distributed hydrologic model in order to improve model simulation accuracy and understand prediction uncertainty at interior ungaged sites of a sparsely gaged watershed. The study is conducted using a distributed version of the HYMOD hydrologic model (HYMOD-DS) applied to the Kabul River basin. Several calibration experiments are conducted to understand the benefits and costs associated with different calibration choices, including (1) whether multisite gaged data should be used simultaneously or in a stepwise manner during model fitting, (2) the effects of increasing parameter complexity, and (3) the potential to estimate interior watershed flows using only gaged data at the basin outlet. The implications of the different calibration strategies are considered in the context of hydrologic projections under climate change. To address the research questions, high-performance computing is utilized to manage the computational burden that results from high-dimensional optimization problems. Several interesting results emerge from the study. The simultaneous use of multisite data is shown to improve the calibration over a stepwise approach, and both multisite approaches far exceed a calibration based on only the basin outlet. The basin outlet calibration can lead to projections of mid-21st century streamflow that deviate substantially from projections under multisite calibration strategies, supporting the use of caution when using distributed models in data-scarce regions for climate change impact assessments. Surprisingly, increased parameter complexity does not substantially increase the uncertainty in streamflow projections, even though parameter equifinality does emerge. The results suggest that increased (excessive) parameter complexity does not always lead to increased predictive uncertainty if structural uncertainties are present. The largest uncertainty in future streamflow results from variations in projected climate between climate models, which substantially outweighs the calibration uncertainty. © 2015 Author(s).
Indexed keywords
| Engineering controlled terms: | CalibrationClimate modelsOptimizationStream flowWatersheds |
|---|---|
| Engineering uncontrolled terms | Calibration experimentsCalibration uncertaintyClimate change impact assessmentsDistributed hydrologic modelHigh performance computingHigh-dimensional optimizationSpatially distributed hydrologic modelingUncertainty of calibration |
| Engineering main heading: | Climate change |
| GEOBASE Subject Index: | calibrationclimate changehydrological modelingoptimizationspatial distributionstreamflowwatershed |
| Regional Index: | Kabul Basin |
- ISSN: 10275606
- Source Type: Journal
- Original language: English
- DOI: 10.5194/hess-19-857-2015
- Document Type: Article
- Publisher: Copernicus GmbH
Wi, S.; Department of Civil and Environmental Engineering, University of Massachusetts, Amherst, MA, United States
© Copyright 2015 Elsevier B.V., All rights reserved.
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