Scrutinizing parameter consistency and predictive uncertainty in rainfall-runoff models using Bayesian total error analysis

Kavetski, Dmitri; Thyer, Mark; Renard, Benjamin; Kuczera, George; Franks, Stewart; Srikanthan, Sri

Title: Scrutinizing parameter consistency and predictive uncertainty in rainfall-runoff models using Bayesian total error analysis
Creator: Kavetski, Dmitri; Thyer, Mark; Renard, Benjamin; Kuczera, George; Franks, Stewart; Srikanthan, Sri
Relation: World Environmental and Water Resources Congress 2008. Proceedings of the World Environmental and Water Resources Congress 2008 (Honolulu, Hawaii 12-16 May, 2008)
Relation: http://content.asce.org/conferences/ewri2008
Publisher: American Society of Civil Engineers (ASCE)
Resource Type: conference paper
Date: 2008
Description: The lack of a robust framework for quantifying the uncertainty in the parameters and predictions of conceptual rainfall runoff (CRR) models remains a key challenge for hydrological science. The Bayesian total error analysis (BATEA) provides a systematic approach to hypothesize, infer and evaluate probability models describing input, output and model structural error. This paper compares the ability of BATEA and standard calibration approaches (standard least squares (SLS) and weighted least squares (WLS)) to address two key requirements of uncertainty assessment: (i) reliable quantification of predictive uncertainty and (ii) reliable estimation of parameter uncertainty. The case study was challenging due to the semi-arid climate, ephemeral responses and high rainfall gradients in the catchment. The post-calibration diagnostics suggest that BATEA provided a considerable improvement over SLS/WLS in terms of satisfying the assumed probability models. This was also confirmed using a novel quantile-based diagnostic for assessing whether the total predictive uncertainty is consistent with the observations. Parameter consistency and reliability was evaluated by comparing parameter estimates obtained for the same CRR model with same catchment runoff, but with different rainfall gauges and time periods. BATEA provided more consistent, albeit more uncertain, parameter estimates than SLS/WLS. The implication for CRR parameter regionalization is that the WLS/SLS-derived parameter estimates can be highly dependent on the choice of rainfall data and calibration period, which may obscure the relationship between CRR parameters and catchment attributes. In contrast, BATEA has the potential to remove this obstacle to regionalization.
Subject: conceptual rainfall runoff; Bayesian total error analysis (BATEA); parameter consistency; rainfall data
Identifier: uon:6094
Identifier: http://hdl.handle.net/1959.13/802451
Identifier: ISBN:9780784409763
Reviewed

Hits: 1577
Visitors: 1879
Downloads: 0

		Thumbnail	File	Description	Size	Format