Litcius/Paper detail

Application of nature-inspired optimization algorithms to ANFIS model to predict wave-induced scour depth around pipelines

Ahmad Sharafati, Ali Tafarojnoruz, Davide Motta, Zaher Mundher Yaseen‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬

2020Journal of Hydroinformatics27 citationsDOIOpen Access PDF

Abstract

Abstract Wave-induced scour depth below pipelines is a physically complex phenomenon, whose reliable prediction may be challenging for pipeline designers. This study shows the application of adaptive neuro-fuzzy inference system (ANFIS) incorporated with particle swarm optimization , ant colony (), differential evolution and genetic algorithm () and assesses the scour depth prediction performance and associated uncertainty in different scour conditions including live-bed and clear-water. To this end, the non-dimensional parameters Shields number (), Keulegan–Carpenter number () and embedded depth to diameter of pipe ratio () are considered as prediction variables. Results indicate that the model ( and ) is the most accurate predictive model in both scour conditions when all three mentioned non-dimensional input parameters are included. Besides, the model shows a better prediction performance than recently developed models. Based on the uncertainty analysis results, the prediction of scour depth is characterized by larger uncertainty in the clear-water condition, associated with both model structure and input variable combination, than in live-bed condition. Furthermore, the uncertainty in scour depth prediction for both live-bed and clear-water conditions is due more to the input variable combination than it is due to the model structure .

Topics & Concepts

Particle swarm optimizationAdaptive neuro fuzzy inference systemVariable (mathematics)Pipeline (software)Inference systemAnt colony optimization algorithmsAlgorithmDifferential evolutionPipeline transportEngineeringComputer scienceMarine engineeringFuzzy logicMathematicsArtificial intelligenceFuzzy control systemMathematical analysisEnvironmental engineeringMechanical engineeringHydrology and Sediment Transport ProcessesHydraulic flow and structuresHydrological Forecasting Using AI