Prediction of Endpoint Sulfur Content in KR Desulfurization Based on the Hybrid Algorithm Combining Artificial Neural Network With SAPSO

In the present work, the endpoint sulfur content prediction model of Kambara Reactor (KR) desulfurization in the steelmaking process is investigated. For Artificial Neural Network (ANN), the effects of different structure parameters, including the number of hidden layer neurons, activation functions...

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Bibliographic Details
Published inIEEE access Vol. 8; pp. 33778 - 33791
Main Authors Wu, Siwei, Yang, Jian, Zhang, Runhao, Ono, Hideki
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 2020
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Accuracy
Algorithms
Artificial neural network
Artificial neural networks
Biological neural networks
Correlation coefficients
Desulfurizing
KR desulfurization process
Mathematical models
Metals
Model accuracy
multiple linear regression
Neural networks
Neurons
particle swarm optimization
Prediction algorithms
Prediction models
prediction of endpoint sulfur content
Predictive models
Process parameters
Regression analysis
Root-mean-square errors
Steel making
Sulfur
Sulfur content
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Summary:In the present work, the endpoint sulfur content prediction model of Kambara Reactor (KR) desulfurization in the steelmaking process is investigated. For Artificial Neural Network (ANN), the effects of different structure parameters, including the number of hidden layer neurons, activation functions and training functions, on the performance of desulfurization model are studied. The initial weights and biases of the neural network is optimized to further elevated the prediction accuracy of the model. Three models established by using Multiple Linear Regression (MLR), ANN and a hybrid algorithm (artificial neural network optimized by SAPSO, named SAPSO-ANN) are compared by the Correlation Coefficient (R), Root Mean Square Error (RMSE) and Mean Absolute Relative Error (MARE). The results show that in the process of KR desulfurization, the nonlinear model of ANN and SAPSO-ANN has a higher accuracy than the linear model of MLR. Among the three models, the SAPSO-ANN model achieves the highest accuracy with R value of 0.54, RMSE of 2.61×10 -4 % and MAER of 0.47, which is selected to analyze the effect of process parameters on the desulfurization rate and design the amount of desulfurization flux in the KR desulfurization process. Experimental results show good agreements with the calculation results, indicating the practicability of the model.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2020.2971517