Toward diagnostic model calibration and evaluation: Approximate Bayesian computation

The ever increasing pace of computational power, along with continued advances in measurement technologies and improvements in process understanding has stimulated the development of increasingly complex hydrologic models that simulate soil moisture flow, groundwater recharge, surface runoff, root w...

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Bibliographic Details
Published in:Water resources research 2013-07, Vol.49 (7), p.4335-4345
Main Authors: Vrugt, Jasper A., Sadegh, Mojtaba
Format: Article
Language:English
Subjects:
approximate Bayesian computation
Bayesian analysis
computational statistics
Freshwater
Groundwater recharge
Groundwater runoff
hydrologic modeling
Hydrologic models
Power
rainfall-runoff transformation
River discharge
River flow
Soil moisture
Statistical methods
Surface runoff
Water uptake
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Summary:The ever increasing pace of computational power, along with continued advances in measurement technologies and improvements in process understanding has stimulated the development of increasingly complex hydrologic models that simulate soil moisture flow, groundwater recharge, surface runoff, root water uptake, and river discharge at different spatial and temporal scales. Reconciling these high‐order system models with perpetually larger volumes of field data is becoming more and more difficult, particularly because classical likelihood‐based fitting methods lack the power to detect and pinpoint deficiencies in the model structure. Gupta et al. (2008) has recently proposed steps (amongst others) toward the development of a more robust and powerful method of model evaluation. Their diagnostic approach uses signature behaviors and patterns observed in the input‐output data to illuminate to what degree a representation of the real world has been adequately achieved and how the model should be improved for the purpose of learning and scientific discovery. In this paper, we introduce approximate Bayesian computation (ABC) as a vehicle for diagnostic model evaluation. This statistical methodology relaxes the need for an explicit likelihood function in favor of one or multiple different summary statistics rooted in hydrologic theory that together have a clearer and more compelling diagnostic power than some average measure of the size of the error residuals. Two illustrative case studies are used to demonstrate that ABC is relatively easy to implement, and readily employs signature based indices to analyze and pinpoint which part of the model is malfunctioning and in need of further improvement. Key Points Approximate Bayesian Computation for diagnostic model calibration and evaluation General purpose methodology to assess which parts of the model are in error An ensemble of signatures is required to extract the information from the data.
ISSN:0043-1397
1944-7973
DOI:10.1002/wrcr.20354