Gingivitis detection by Fractional Fourier Entropy and Particle Swarm Optimization

Yan, Yan (2021) Gingivitis detection by Fractional Fourier Entropy and Particle Swarm Optimization. EAI Endorsed Transactions on e-Learning, 7 (21). e5. ISSN 2032-9253

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INTRODUCTION: we propose a detection model of gingivitis based on feature extraction based on particle swarm optimization neural network with fractional Fourier entropy. OBJECTIVES: For the sake of reduce the diagnostic burden of doctors' frequent and high concentration. METHODS: Primarily, Fourier transform is applied to the collected image signal, and the entropy is extracted from the gingival image by Shannon entropy so as to get the input value. The particle swarm optimization algorithm was combined with the extraction eigenvector is used to detect whether patients have gingivitis in final. RESULTS: The experimental results show that this method can reduce the unnecessary space of image detection, reduce the complexity of image information, and achieve a sensitivity of 79.00±1.61%, specificity of 80.89±1.87% and accuracy of 79.94±0.96%. CONCLUSION: This optimized algorithm can effectively and accurately cluster the sample data, and the accuracy is also higher than the advanced gingival image diagnosis method, making the gingivitis diagnosis more accurate. Our neural network has good trainability and recognition ability, which makes a unique contribution to medically intelligent detection methods for gingival treatment.

Item Type: Article
Uncontrolled Keywords: Multi-layer perception, gingivitis detection, fractional Fourier entropy, particle swarm optimization, detection algorithm
Subjects: H Social Sciences > H Social Sciences (General)
Q Science > QA Mathematics > QA75 Electronic computers. Computer science
QA75 Electronic computers. Computer science
Depositing User: EAI Editor IV
Date Deposited: 09 Jul 2021 08:28
Last Modified: 09 Jul 2021 08:28

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