CAD-CKD: a computer aided diagnosis system for chronic kidney disease using automated BiGSqENet in the Internet of Things platform

A fast and efficient disease diagnosis system based on IoT data is challenging since the data has high data redundancy. To formulate this, many pre-processing techniques and feature-based classification techniques are used. However, the processing time and the computational effort of these processes...

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Bibliographic Details
Published in:Evolving systems 2024-08, Vol.15 (4), p.1487-1502
Main Authors: Venkatrao, Kommuri, Shaik, Kareemulla
Format: Article
Language:English
Subjects:
Accuracy
Artificial Intelligence
Artificial neural networks
Big Data
Cloud computing
Clustering
Complex Systems
Complexity
Datasets
Decision making
Deep learning
Density ratio
Diagnosis
Engineering
Entropy
Feature selection
Internet of Things
Kidney diseases
Machine learning
Monitoring systems
Neural networks
Optimization algorithms
Original Paper
Redundancy
Citations: Items that this one cites
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Summary:A fast and efficient disease diagnosis system based on IoT data is challenging since the data has high data redundancy. To formulate this, many pre-processing techniques and feature-based classification techniques are used. However, the processing time and the computational effort of these processes are high. To counteract this, this article introduces a novel outlier removal model that uses a three-step clustering process. Instead of using distance- or density-based clustering, a directional density ratio is evaluated here, which provides the direction, distance, and density of the samples. Based on the directional density ratio, samples are clustered using K-Means, Reverse K-Nearest, and agglomerative clustering methods. The clustered features are provided as input to a novel deep neural network that hybridizes bidirectional GRU and squeeze-and-excitation residual networks. To improve the accuracy of the prediction, a Multiverse Jackal optimization (MJO) is used, which reduces the cross-entropy of the proposed classifier. As a result, the proposed method has resulted in an accuracy of 99.8% with an execution time of 103.7 ms, which is 33.6% faster than existing state-of-the-art methods.
ISSN:1868-6478
1868-6486
DOI:10.1007/s12530-024-09571-y