Correlation-Based Weight Adjusted Naive Bayes

Naive Bayes (NB) is an extremely simple and remarkably effective approach to classification learning, but its conditional independence assumption rarely holds true in real-world applications. Attribute weighting is known as a flexible model via assigning each attribute a different weight discriminat...

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Veröffentlicht in:	IEEE access 2020, Vol.8, p.51377-51387
Hauptverfasser:	Yu, Liangjun, Gan, Shengfeng, Chen, Yu, He, Meizhang
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Sprache:	eng
Schlagworte:	attribute weighting Classification Complexity Correlation Decision trees Education Linear programming Naive Bayes Redundancy Time complexity weight adjustment Weight measurement Weighting
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description	Naive Bayes (NB) is an extremely simple and remarkably effective approach to classification learning, but its conditional independence assumption rarely holds true in real-world applications. Attribute weighting is known as a flexible model via assigning each attribute a different weight discriminatively to improve NB. Attribute weighting approaches can fall into two broad categories: filters and wrappers. Wrappers receive a bigger boost in terms of classification accuracy compared with filters, but the time complexity of wrappers is much higher than filters. In order to improve the time complexity of a wrapper, a filter can be used to optimize the initial weight of all attributes as a preprocessing step. So a hybrid attribute weighting approach is proposed in this paper, and the improved model is called correlation-based weight adjusted naive Bayes (CWANB). In CWANB, the correlation-based attribute weighting filter is used to initialize the attribute weights, and then each weight is optimized by the attribute weight adjustment wrapper where the objective function is designed based on dynamic adjustment of attribute weights. Extensive experimental results show that CWANB outperforms NB and some other existing state-of-the-art attribute weighting approaches in terms of the classification accuracy. Meanwhile, compared with the existing wrapper, the CWANB approach reduces the time complexity dramatically.
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subjects	attribute weighting Classification Complexity Correlation Decision trees Education Linear programming Naive Bayes Redundancy Time complexity weight adjustment Weight measurement Weighting
title	Correlation-Based Weight Adjusted Naive Bayes
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