A multilayer perceptron-based prediction of ammonium adsorption on zeolite from landfill leachate: Batch and column studies.

In this study, multilayer perceptron (MLP) artificial neural network was used to predict the adsorption rate of ammonium on zeolite. pH, inlet ammonium concentration, contact time, temperature, dosage of adsorbent, agitation speed, and particle size in the batch experiments were used as independent variables while flow rate and particle size in column mode were investigated. In MLP application, different architecture structures were tried and the architecture structures with the highest predictive performance were determined. To comparatively evaluate the predictive capabilities of MLP based prediction tool, Response Surface Methodology (RSM) was utilized. When the results were evaluated with Root Mean Square Error (RMSE) and Mean Absolute Percentage Error (MAPE) values (<1%) for almost all experiments, it was seen that MLP-based prediction tool produces better predictions than RSM. The scatter plots showed that predictions and actual values were quite compatible. Both regression and determination coefficients were interpreted by creating a regression of the predictions against the actual values and these coefficients were obtained as pretty close to 1. The outstanding performance of MLP in out-of-sample data sets without the need for additional experiment demonstrate that MLP can be effectively and reliably used in cases where experimental setups are difficult or costly. Copyright © 2020 Elsevier B.V. All rights reserved.

Citation

Fulya Aydın Temel, Özge Cağcağ Yolcu, Ayşe Kuleyin. A multilayer perceptron-based prediction of ammonium adsorption on zeolite from landfill leachate: Batch and column studies. Journal of hazardous materials. 2021 May 15;410:124670

PMID: 33272729

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