Abstract
The Muskingum model is a popular hydrologic flood routing technique; however, the accurate estimation of model parameters challenges the effective, precise, and rapid-response operation of flood routing. Evolutionary and metaheuristic optimization algorithms (EMOAs) are well suited for parameter estimation task associated with a wide range of complex models including the nonlinear Muskingum model. However, more proficient frameworks requiring less computational effort are substantially advantageous. Among the EMOAs teaching–learning-based optimization (TLBO) is a relatively new, parameter-free, and efficient metaheuristic optimization algorithm, inspired by the teacher-student interactions in a classroom to upgrade the overall knowledge of a topic through a teaching–learning procedure. The novelty of this study originates from (1) coupling TLBO and the nonlinear Muskingum routing model to estimate the Muskingum parameters by outflow predictability enhancement, and (2) evaluating a parameter-free algorithm’s functionality and accuracy involving complex Muskingum model’s parameter determination. TLBO, unlike previous EMOAs linked to the Muskingum model, is free of algorithmic parameters which makes it ideal for prediction without optimizing EMOAs parameters. The hypothesis herein entertained is that TLBO is effective in estimating the nonlinear Muskingum parameters efficiently and accurately. This hypothesis is evaluated with two popular benchmark examples, the Wilson and Wye River case studies. The results show the excellent performance of the “TLBO-Muskingum” for estimating accurately the Muskingum parameters based on the Nash–Sutcliffe Efficiency (NSE) to evaluate the TLBO’s predictive skill using benchmark problems. The NSE index is calculated 0.99 and 0.94 for the Wilson and Wye River benchmarks, respectively.
Highlights
The Muskingum model is a popular hydrologic flood routing technique; the accurate estimation of model parameters challenges the effective, precise, and rapid-response operation of flood routing
The performance of the “teaching–learning-based optimization (TLBO)-Muskingum” in estimating the three-parameters of nonlinear Muskingum model is evaluated with two well-known benchmark problems: (1) the Wilson cased s tudy[47], and (2) the River Wye in the United Kingdom[48], both with one single peak flood event
The former one is a popular benchmark problem based on the data provided by Wilson (1974) and has been employed commonly in several studies[9,14,22,50,51,52,53] to be linked to Evolutionary and metaheuristic optimization algorithms (EMOAs) for estimation of nonlinear Muskingum model’s parameters
Summary
The Muskingum model is a popular hydrologic flood routing technique; the accurate estimation of model parameters challenges the effective, precise, and rapid-response operation of flood routing. The hypothesis entertained is that TLBO is effective in estimating the nonlinear Muskingum parameters efficiently and accurately This hypothesis is evaluated with two popular benchmark examples, the Wilson and Wye River case studies. The three-parameter nonlinear Muskingum model features storage-time parameter ( K ), dimensionless river reach weighting factor (χ ), and dimensionless nonlinear flood wave (m) parameters, which must be estimated by traditional mathematical techniques or evolutionary and metaheuristic optimization algorithms (EMOAs)[8]. This study proposes the TLBO algorithm coupled with nonlinear Muskingum routing to estimate the parameters of the flood routing model to overcome the limitations of the search techniques and the calibration of evolutionary algorithmic parameters. This work evaluates the “TLBO-Muskingum” framework’s performance The successful TLBO application in this work may encourage its use in other hydrologic problems
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