A New Type of Fuzzy-Rule-Based System With Chaotic Swarm Intelligence for Multiclassification of Pain Perception From fMRI

Machine learning has been increasingly used in decoding brain states from functional magnetic resonance imaging (fMRI). One important application is to classify the levels of pain perception from patients' fMRI for clinical pain assessment. However, the huge number of fMRI features and the comp...

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Published in:IEEE transactions on fuzzy systems 2020-06, Vol.28 (6), p.1096-1109
Main Authors: Anter, Ahmed M., Huang, Gan, Li, Linling, Zhang, Li, Liang, Zhen, Zhang, Zhiguo
Format: Article
Language:English
Subjects:
Chaos theory
Classification
Convergence
Crow search optimization (CSO)
Decoding
Feature extraction
Functional magnetic resonance imaging
functional magnetic resonance imaging (fMRI) decoding
Fuzzy logic
fuzzy rules
Fuzzy systems
Machine learning
Magnetic resonance imaging
Multilayers
Optimization
Pain
pain prediction
Perception
Prototypes
self-organizing fuzzy logic prototype (SOFLP)
Swarm intelligence
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cited_by cdi_FETCH-LOGICAL-c295t-e9ada0988ff338900664d62ff2b1eed012a4d897cf7c86014a319c2344ed42003
cites cdi_FETCH-LOGICAL-c295t-e9ada0988ff338900664d62ff2b1eed012a4d897cf7c86014a319c2344ed42003
container_end_page 1109
container_issue 6
container_start_page 1096
container_title IEEE transactions on fuzzy systems
container_volume 28
creator Anter, Ahmed M.
Huang, Gan
Li, Linling
Zhang, Li
Liang, Zhen
Zhang, Zhiguo
description Machine learning has been increasingly used in decoding brain states from functional magnetic resonance imaging (fMRI). One important application is to classify the levels of pain perception from patients' fMRI for clinical pain assessment. However, the huge number of fMRI features and the complex relationships between fMRI and pain levels affect the performance of pain classification models heavily. In this article, we introduce a new fuzzy-rule-based hybrid optimization approach for dimension reduction and multiclassification problems using chaotic map, crow search optimization (CSO), and self-organizing fuzzy logic prototype (SOFLP). The approach is named as CCSO-SOFLP. In the proposed approach, chaotic map-based CSO is employed to find the optimal features from ultra-high-dimensional fMRI, and the fuzzy-rule-based SOFLP is employed for multiclassification of pain levels. In this sense, CSO is provided to avoid being stuck in local minima and to increase the computational performance. On the other hand, multilayer SOFLP classifier can continuously learn from new data and identify prototypes from the observed data and use them to build fuzzy rules, to define a suitable local area for each prototype, and to avoid overlapping. The proposed approach is applied on a pain-evoked fMRI data set to classify the levels of pain. Results indicate that the proposed approach can decode levels of pain and identify predictive fMRI patterns with higher accuracy and convergence speed and shorter execution time. Therefore, the new type of fuzzy-rule-based system with chaotic swarm intelligence holds great potential to predict pain perception in clinical uses.
doi_str_mv 10.1109/TFUZZ.2020.2979150
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One important application is to classify the levels of pain perception from patients' fMRI for clinical pain assessment. However, the huge number of fMRI features and the complex relationships between fMRI and pain levels affect the performance of pain classification models heavily. In this article, we introduce a new fuzzy-rule-based hybrid optimization approach for dimension reduction and multiclassification problems using chaotic map, crow search optimization (CSO), and self-organizing fuzzy logic prototype (SOFLP). The approach is named as CCSO-SOFLP. In the proposed approach, chaotic map-based CSO is employed to find the optimal features from ultra-high-dimensional fMRI, and the fuzzy-rule-based SOFLP is employed for multiclassification of pain levels. In this sense, CSO is provided to avoid being stuck in local minima and to increase the computational performance. 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source IEEE Electronic Library (IEL) Journals
subjects Chaos theory
Classification
Convergence
Crow search optimization (CSO)
Decoding
Feature extraction
Functional magnetic resonance imaging
functional magnetic resonance imaging (fMRI) decoding
Fuzzy logic
fuzzy rules
Fuzzy systems
Machine learning
Magnetic resonance imaging
Multilayers
Optimization
Pain
pain prediction
Perception
Prototypes
self-organizing fuzzy logic prototype (SOFLP)
Swarm intelligence
title A New Type of Fuzzy-Rule-Based System With Chaotic Swarm Intelligence for Multiclassification of Pain Perception From fMRI
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