Nature-inspired framework of ensemble learning for collaborative classification in granular computing context

Liu, Ran; Cocea, Mihaela

doi:10.1007/s41066-018-0122-5

Cited by 16 publications

(5 citation statements)

References 40 publications

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“…In other words, the adoption of each way of constructing fuzzy membership functions leads to a specific channel for producing deep rule ensembles through multiple iterations of learning, in order to create the further diversity among the deep rule ensembles produced at different channels, while the depth of learning at each channel is increased independently through involving multiple iterations. In addition, we will investigate how granular computing techniques [10,11,30,35,41,48] can be incorporated effectively into the proposed approach of deep rule ensemble creation towards further increasing the depth of learning.…”

Section: Discussionmentioning

confidence: 99%

Heuristic creation of deep rule ensemble through iterative expansion of feature space

Liu

Chen

2020

Information Sciences

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Rule learning approaches, which essentially aim to gerenate a decision tree or a set of "if-then" rules, have been popularly used in practice for automatically building rule-based models for prediction tasks, e.g., classification and regression. The key strength of rule-based models is their ability to interpret how an output is obtained given an input, in comparison with models trained by other machine learning approaches, e.g., neural networks. Moreover, ensemble learning approaches have been adopted as a popular way for advancing the performance of rule-based prediction through producing multiple rule-based models with diversity. Traditional approaches of ensemble learning are typically designed to train a single ensemble. In recent years, there have been some studies on creation of multiple ensembles towards increasing the diversity among rulebased models and the depth of ensemble learning. In this paper, we propose a feature expansion driven approach for automatic creation of deep rule ensembles, i.e., the dimensionality of the feature space is increased at each iteration by adding features newly created at the previous iteration. The proposed approach is compared with more recent approaches of rule learning and ensemble creation. The experimental results show that the proposed approach achieves improved performance on various data sets.

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Section: Discussionmentioning

confidence: 99%

Heuristic creation of deep rule ensemble through iterative expansion of feature space

Liu

Chen

2020

Information Sciences

Self Cite

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“…In the 3rd step, the fog node builds the consciousness prediction model based on a random forest (RF) algorithm. The use of an RF to predict the GCS using vital signs has returned to several reasons that are: (i) RF gives the ability to measure feature correlation for all features using the Gini index that indicates the impact of each feature in the model [72], (ii) RF compromising the explainability and accuracy issues. Generally, models that have a good performance in terms of classification accuracy as SVM and LDA are not able to provide a clear explanation about the output decision [73], whereas the most tree-based algorithms are very good explainability, but may not be the best algorithm in terms of performance [74], and (iii) RF is a tree-based algorithm that utilized several trees and then combined the final decision using a majority voting algorithm.…”

Section: Fog-assisted Consciousness Management (Facm)mentioning

confidence: 99%

An efficient edge/cloud medical system for rapid detection of level of consciousness in emergency medicine based on explainable machine learning models

El-Rashidy

Sedik

Siam

et al. 2023

Neural Comput & Applic

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Emergency medicine (EM) is one of the attractive research fields in which researchers investigate their efforts to diagnose and treat unforeseen illnesses or injuries. There are many tests and observations are involved in EM. Detection of the level of consciousness is one of these observations, which can be detected using several methods. Among these methods, the automatic estimation of the Glasgow coma scale (GCS) is studied in this paper. The GCS is a medical score used to describe a patient’s level of consciousness. This type of scoring system requires medical examination that may not be available with the shortage of the medical expert. Therefore, the automatic medical calculation for a patient’s level of consciousness is highly needed. Artificial intelligence has been deployed in several applications and appears to have a high performance regarding providing automatic solutions. The main objective of this work is to introduce the edge/cloud system to improve the efficiency of the consciousness measurement through efficient local data processing. Moreover, an efficient machine learning (ML) model to predict the level of consciousness of a certain patient based on the patient’s demographic, vital signs, and laboratory tests is proposed, as well as maintaining the explainability issue using Shapley additive explanations (SHAP) that provides natural language explanation in a form that helps the medical expert to understand the final prediction. The developed ML model is validated using vital signs and laboratory tests extracted from the MIMIC III dataset, and it achieves superior performance (mean absolute error (MAE) = 0.269, mean square error (MSE) = 0.625, R2 score = 0.964). The resulting model is accurate, medically intuitive, and trustworthy.

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“…Using TL, the model starts with initial weights that are just a slight modification. A pre-trained model is used for new tasks in two main ways [15]. The classifier is trained on top of the pre-trained model to perform the classification task after the pre-trained model is treated as a feature extractor.…”

Section: Transfer Learning Approachesmentioning

confidence: 99%

Robust Deep Learning Model for Black Fungus Detection Based on Gabor Filter and Transfer Learning

Hassan,

M. Talaat,

Adel

et al. 2023

Computer Systems Science and Engineering

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Black fungus is a rare and dangerous mycology that usually affects the brain and lungs and could be life-threatening in diabetic cases. Recently, some COVID-19 survivors, especially those with co-morbid diseases, have been susceptible to black fungus. Therefore, recovered COVID-19 patients should seek medical support when they notice mucormycosis symptoms. This paper proposes a novel ensemble deep-learning model that includes three pre-trained models: reset (50), VGG (19), and Inception. Our approach is medically intuitive and efficient compared to the traditional deep learning models. An image dataset was aggregated from various resources and divided into two classes: a black fungus class and a skin infection class. To the best of our knowledge, our study is the first that is concerned with building black fungus detection models based on deep learning algorithms. The proposed approach can significantly improve the performance of the classification task and increase the generalization ability of such a binary classification task. According to the reported results, it has empirically achieved a sensitivity value of 0.9907, a specificity value of 0.9938, a precision value of 0.9938, and a negative predictive value of 0.9907.

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Nature-inspired framework of ensemble learning for collaborative classification in granular computing context

Cited by 16 publications

References 40 publications

Heuristic creation of deep rule ensemble through iterative expansion of feature space

Heuristic creation of deep rule ensemble through iterative expansion of feature space

An efficient edge/cloud medical system for rapid detection of level of consciousness in emergency medicine based on explainable machine learning models

Robust Deep Learning Model for Black Fungus Detection Based on Gabor Filter and Transfer Learning

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