High-Performance Machine Learning for Large-Scale Data Classification considering Class Imbalance

Currently, data classification is one of the most important ways to analysis data. However, along with the development of data collection, transmission, and storage technologies, the scale of the data has been sharply increased. Additionally, due to multiple classes and imbalanced data distribution...

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Bibliographic Details
Published in:Scientific programming 2020, Vol.2020 (2020), p.1-16
Main Authors: Wang, Xi, Chen, Xianbang, Li, Xiang, Liu, Yang, Li, Huaqiang
Format: Article
Language:English
Subjects:
Accuracy
Algorithms
Artificial neural networks
Classification
Clustering
Data collection
Datasets
Efficiency
Machine learning
Neural networks
Oversampling
Parallel processing
Support vector machines
Training
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Summary:Currently, data classification is one of the most important ways to analysis data. However, along with the development of data collection, transmission, and storage technologies, the scale of the data has been sharply increased. Additionally, due to multiple classes and imbalanced data distribution in the dataset, the class imbalance issue is also gradually highlighted. The traditional machine learning algorithms lack of abilities for handling the aforementioned issues so that the classification efficiency and precision may be significantly impacted. Therefore, this paper presents an improved artificial neural network in enabling the high-performance classification for the imbalanced large volume data. Firstly, the Borderline-SMOTE (synthetic minority oversampling technique) algorithm is employed to balance the training dataset, which potentially aims at improving the training of the back propagation neural network (BPNN), and then, zero-mean, batch-normalization, and rectified linear unit (ReLU) are further employed to optimize the input layer and hidden layers of BPNN. At last, the ensemble learning-based parallelization of the improved BPNN is implemented using the Hadoop framework. Positive conclusions can be summarized according to the experimental results. Benefitting from Borderline-SMOTE, the imbalanced training dataset can be balanced, which improves the training performance and the classification accuracy. The improvements for the input layer and hidden layer also enhance the training performances in terms of convergence. The parallelization and the ensemble learning techniques enable BPNN to implement the high-performance large-scale data classification. The experimental results show the effectiveness of the presented classification algorithm.
ISSN:1058-9244
1875-919X
DOI:10.1155/2020/1953461