Mr 2 DNM: A novel mutual information-based dendritic neuron model

Xiaoxiao Qian; Yirui Wang; Shuyang Cao; Yuki Todo; Shangce Gao

doi:10.1155/2019/7362931

Mr 2 DNM: A novel mutual information-based dendritic neuron model

Xiaoxiao Qian, Yirui Wang, Shuyang Cao^*, Yuki Todo, Shangce Gao^*

^*Corresponding author for this work

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16 Scopus citations

Abstract

By employing a neuron plasticity mechanism, the original dendritic neuron model (DNM) has been succeeded in the classification tasks with not only an encouraging accuracy but also a simple learning rule. However, the data collected in real world contain a lot of redundancy, which causes the process of analyzing data by DNM become complicated and time-consuming. This paper proposes a reliable hybrid model which combines a maximum relevance minimum redundancy (Mr2) feature selection technique with DNM (namely, Mr2DNM) for classifying the practical classification problems. The mutual information-based Mr2 is applied to evaluate and rank the most informative and discriminative features for the given dataset. The obtained optimal feature subset is used to train and test the DNM for classifying five different problems arisen from medical, physical, and social scenarios. Experimental results suggest that the proposed Mr2DNM outperforms DNM and other six classification algorithms in terms of accuracy and computational efficiency.

Original language	English
Article number	7362931
Journal	Computational intelligence and neuroscience
Volume	2019
DOIs	https://doi.org/10.1155/2019/7362931
State	Published - 2019

ASJC Scopus subject areas

General Computer Science
General Neuroscience
General Mathematics

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title = "Mr 2 DNM: A novel mutual information-based dendritic neuron model",

abstract = "By employing a neuron plasticity mechanism, the original dendritic neuron model (DNM) has been succeeded in the classification tasks with not only an encouraging accuracy but also a simple learning rule. However, the data collected in real world contain a lot of redundancy, which causes the process of analyzing data by DNM become complicated and time-consuming. This paper proposes a reliable hybrid model which combines a maximum relevance minimum redundancy (Mr2) feature selection technique with DNM (namely, Mr2DNM) for classifying the practical classification problems. The mutual information-based Mr2 is applied to evaluate and rank the most informative and discriminative features for the given dataset. The obtained optimal feature subset is used to train and test the DNM for classifying five different problems arisen from medical, physical, and social scenarios. Experimental results suggest that the proposed Mr2DNM outperforms DNM and other six classification algorithms in terms of accuracy and computational efficiency.",

author = "Xiaoxiao Qian and Yirui Wang and Shuyang Cao and Yuki Todo and Shangce Gao",

note = "Publisher Copyright: {\textcopyright} 2019 Xiaoxiao Qian et al.",

year = "2019",

doi = "10.1155/2019/7362931",

language = "英語",

volume = "2019",

journal = "Computational intelligence and neuroscience",

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TY - JOUR

T1 - Mr 2 DNM

T2 - A novel mutual information-based dendritic neuron model

AU - Qian, Xiaoxiao

AU - Wang, Yirui

AU - Cao, Shuyang

AU - Todo, Yuki

AU - Gao, Shangce

PY - 2019

Y1 - 2019

N2 - By employing a neuron plasticity mechanism, the original dendritic neuron model (DNM) has been succeeded in the classification tasks with not only an encouraging accuracy but also a simple learning rule. However, the data collected in real world contain a lot of redundancy, which causes the process of analyzing data by DNM become complicated and time-consuming. This paper proposes a reliable hybrid model which combines a maximum relevance minimum redundancy (Mr2) feature selection technique with DNM (namely, Mr2DNM) for classifying the practical classification problems. The mutual information-based Mr2 is applied to evaluate and rank the most informative and discriminative features for the given dataset. The obtained optimal feature subset is used to train and test the DNM for classifying five different problems arisen from medical, physical, and social scenarios. Experimental results suggest that the proposed Mr2DNM outperforms DNM and other six classification algorithms in terms of accuracy and computational efficiency.

AB - By employing a neuron plasticity mechanism, the original dendritic neuron model (DNM) has been succeeded in the classification tasks with not only an encouraging accuracy but also a simple learning rule. However, the data collected in real world contain a lot of redundancy, which causes the process of analyzing data by DNM become complicated and time-consuming. This paper proposes a reliable hybrid model which combines a maximum relevance minimum redundancy (Mr2) feature selection technique with DNM (namely, Mr2DNM) for classifying the practical classification problems. The mutual information-based Mr2 is applied to evaluate and rank the most informative and discriminative features for the given dataset. The obtained optimal feature subset is used to train and test the DNM for classifying five different problems arisen from medical, physical, and social scenarios. Experimental results suggest that the proposed Mr2DNM outperforms DNM and other six classification algorithms in terms of accuracy and computational efficiency.

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JO - Computational intelligence and neuroscience

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Mr 2 DNM: A novel mutual information-based dendritic neuron model

Abstract

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