A robust Gauss-Newton algorithm for the optimization of hydrological models: from standard Gauss-Newton to robust Gauss-Newton

Qin, Youwei; Kavetski, Dmitri; Kuczera, George

Title: A robust Gauss-Newton algorithm for the optimization of hydrological models: from standard Gauss-Newton to robust Gauss-Newton
Creator: Qin, Youwei; Kavetski, Dmitri; Kuczera, George
Relation: Water Resources Research Vol. 54, Issue 11, p. 9655-9683
Publisher Link: http://dx.doi.org/10.1029/2017WR022488
Publisher: Wiley-Blackwell
Resource Type: journal article
Date: 2018
Description: Model calibration using optimization algorithms is a perennial challenge in hydrological modeling. This study explores opportunities to improve the efficiency of a Newton‐type method by making it more robust against problematic features in models' objective functions, including local optima and other noise. We introduce the robust Gauss‐Newton (RGN) algorithm for least squares optimization, which employs three heuristic schemes to enhance its exploratory abilities while keeping costs low. The large sampling scale (LSS) scheme is a central difference approximation with perturbation (sampling scale) made as large as possible to capture the overall objective function shape; the best‐sampling point (BSP) scheme exploits known function values to detect better parameter locations; and the null‐space jump (NSJ) scheme attempts to escape near‐flat regions. The RGN heuristics are evaluated using a case study comprising four hydrological models and three catchments. The heuristics make synergistic contributions to overall efficiency: the LSS scheme substantially improves reliability albeit at the expense of increased costs, and scenarios where LSS on its own is ineffective are bolstered by the BSP and NSJ schemes. In 11 of 12 modeling scenarios, RGN is 1.4–18 times more efficient in finding the global optimum than the standard Gauss‐Newton algorithm; similar gains are made in finding tolerable optima. Importantly, RGN offers its largest gains when working with difficult objective functions. The empirical analysis provides insights into tradeoffs between robustness versus cost, exploration versus exploitation, and how to manage these tradeoffs to maximize optimization efficiency. In the companion paper, the RGN algorithm is benchmarked against industry standard optimization algorithms.
Subject: hydrological model calibration; parameter optimization; robust Gauss-Newton algoritm; coarse gradient approximation; reliability-cost tradeoffs; algoritm efficiency
Identifier: http://hdl.handle.net/1959.13/1411120
Identifier: uon:36293
Identifier: ISSN:0043-1397
Rights: An edited version of this paper was published by AGU. Copyright 2018 American Geophysical Union. AQin, Y., Kavetski, D., & Kuczera, G. ( 2018). A robust Gauss‐Newton algorithm for the optimization of hydrological models: From standard Gauss‐Newton to robust Gauss‐Newton. Water Resources Research, 54, 9655– 9683 DOI 10.1029/2017WR022488. To view the published open abstract, go to http://dx.doi.org and enter the DOI.
Language: eng
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