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Adaptive Optimization-Enabled Neural Networks to Handle the Imbalance Churn Data in Churn Prediction

Bharathi Garimella

Department of Computer Science and Engineering, Jawaharlal Nehru Technological University, Kakinada, AP, India

E-mail Address: bgarimella42@gmail.com

Corresponding author.

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G. V. S. N. R. V. Prasad

Department of Computer Science and Engineering, Gudlavalleru Engineering College, Gudlavalleru, AP, India

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, and

M. H. M. Krishna Prasad

Department of Computer Science and Engineering, Jawaharlal Nehru Technological University, Kakinada, AP, India

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https://doi.org/10.1142/S1469026821500255Cited by:1 (Source: Crossref)

Abstract

The churn prediction based on telecom data has been paid great attention because of the increasing the number telecom providers, but due to inconsistent data, sparsity, and hugeness, the churn prediction becomes complicated and challenging. Hence, an effective and optimal prediction of churns mechanism, named adaptive firefly-spider optimization (adaptive FSO) algorithm, is proposed in this research to predict the churns using the telecom data. The proposed churn prediction method uses telecom data, which is the trending domain of research in predicting the churns; hence, the classification accuracy is increased. However, the proposed adaptive FSO algorithm is designed by integrating the spider monkey optimization (SMO), firefly optimization algorithm (FA), and the adaptive concept. The input data is initially given to the master node of the spark framework. The feature selection is carried out using Kendall’s correlation to select the appropriate features for further processing. Then, the selected unique features are given to the master node to perform churn prediction. Here, the churn prediction is made using a deep convolutional neural network (DCNN), which is trained by the proposed adaptive FSO algorithm. Moreover, the developed model obtained better performance using the metrics, like dice coefficient, accuracy, and Jaccard coefficient by varying the training data percentage and selected features. Thus, the proposed adaptive FSO-based DCNN showed improved results with a dice coefficient of 99.76%, accuracy of 98.65%, Jaccard coefficient of 99.52%.

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