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Prediction of bedload transport rate using a block combined network structure

Seyed Abbas Hosseini, Abbas Abbaszadeh Shahri, Reza Asheghi

2021Hydrological Sciences Journal57 citationsDOI

Abstract

Modularity as a system of separate and independent sub-tasks is the appropriate way to improve the performance of artificial neural network (ANN) models in hydrological processes. Using this approach, a block combined neural network (BCNN) structure incorporated with genetic algorithm (GA) and an additional decision block is suggested in this study. The optimum topology of embedded networks in each block was detected using a vector-based method subjected to different internal characteristics. This model was then applied on 879 bedload datasets, considering velocity, discharge, mean grain size, slope, and depth as model inputs over streams in Idaho, USA. The correct classification rate of predicted bedload using BCNN (89.77%) showed superior performance accuracy compared to other ANNs, and to empirical models. Results of computed error metrics and confusion matrixes also demonstrated outstanding progress in BCNN relative to other models. We show that BCNN as a new method with an appropriate accuracy level could effectively be adopted for bedload prediction purposes.

Topics & Concepts

Bed loadBlock (permutation group theory)Artificial neural networkComputer scienceModularity (biology)Genetic algorithmData miningGeologyArtificial intelligenceMachine learningMathematicsSediment transportGeometryGeneticsSedimentBiologyPaleontologyHydrology and Watershed Management StudiesHydrology and Sediment Transport ProcessesHydrological Forecasting Using AI
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