Reconstruction and analysis of negatively buoyant jets with interpretable machine learning

• URL: http://arxiv.org/abs/2211.05489v1
• Date: Thu, 10 Nov 2022 11:14:45 GMT
• Title: Reconstruction and analysis of negatively buoyant jets with interpretable machine learning
• Authors: Marta Alvir, Luka Grb\v{c}i\'c, Ante Sikirica, Lado Kranj\v{c}evi\'c
• Abstract summary: negatively inclined buoyant jets are observed during the discharge of wastewater from processes such as desalination. To minimize harmful effects and assess environmental impact, a detailed numerical investigation is necessary. The application of machine learning models is proposed.
• Score: 0.0
• License: http://creativecommons.org/licenses/by-nc-nd/4.0/
• Abstract: In this paper, negatively inclined buoyant jets, which appear during the discharge of wastewater from processes such as desalination, are observed. To minimize harmful effects and assess environmental impact, a detailed numerical investigation is necessary. The selection of appropriate geometry and working conditions for minimizing such effects often requires numerous experiments and numerical simulations. For this reason, the application of machine learning models is proposed. Several models including Support Vector Regression, Artificial Neural Networks, Random Forests, XGBoost, CatBoost and LightGBM were trained. The dataset was built with numerous OpenFOAM simulations, which were validated by experimental data from previous research. The best prediction was obtained by Artificial Neural Network with an average of R2 0.98 and RMSE 0.28. In order to understand the working of the machine learning model and the influence of all parameters on the geometrical characteristics of inclined buoyant jets, the SHAP feature interpretation method was used.

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