Development of a Diabetes Diagnosis System Using Machine Learning Algorithms

Victor Chang; Keerthi Kandadai; Qianwen Ariel Xu; Steven Guan

doi:10.4018/IJDST.296246

Development of a Diabetes Diagnosis System Using Machine Learning Algorithms

Victor Chang^*, Keerthi Kandadai, Qianwen Ariel Xu, Steven Guan

^*Corresponding author for this work

Department of Computing

Research output: Contribution to journal › Article › peer-review

Abstract

This paper describes how to develop diabetes diagnosis through the combined use of the support vector machine, the decision tree, naive bayes, k-nearest, and finally, random forest (RF) algorithms. These methods are useful to predict diabetes jointly. The appropriateness of ML-depended techniques to tackle this issue has been revealed. This diabetes diagnosis system using machine-learning algorithms is used to review papers. This project was based on developing Python-based code for machine learning algorithms to perform large scale diabetes analysis. The hardware requirement of machine learning is RAM that is 128 GB DDR4 2133 MHz and 2 TB Hard Disk and needs 512 GB SSD. One standard library is NumPy, which is used to support multi-dimensional arrays objects, various components, and matrices. The random forest prediction representing the pictorial visualization of the model and the accuracy for the data analysis using the random forest is 76%.

Original language	English
Journal	International Journal of Distributed Systems and Technologies
Volume	13
Issue number	1
DOIs	https://doi.org/10.4018/IJDST.296246
Publication status	Published - 2022

Keywords

Diabetes Diagnosis
Machine Learning for Healthcare
Random Forest Prediction

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.4018/IJDST.296246

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title = "Development of a Diabetes Diagnosis System Using Machine Learning Algorithms",

abstract = "This paper describes how to develop diabetes diagnosis through the combined use of the support vector machine, the decision tree, naive bayes, k-nearest, and finally, random forest (RF) algorithms. These methods are useful to predict diabetes jointly. The appropriateness of ML-depended techniques to tackle this issue has been revealed. This diabetes diagnosis system using machine-learning algorithms is used to review papers. This project was based on developing Python-based code for machine learning algorithms to perform large scale diabetes analysis. The hardware requirement of machine learning is RAM that is 128 GB DDR4 2133 MHz and 2 TB Hard Disk and needs 512 GB SSD. One standard library is NumPy, which is used to support multi-dimensional arrays objects, various components, and matrices. The random forest prediction representing the pictorial visualization of the model and the accuracy for the data analysis using the random forest is 76%.",

keywords = "Diabetes Diagnosis, Machine Learning for Healthcare, Random Forest Prediction",

author = "Victor Chang and Keerthi Kandadai and Xu, {Qianwen Ariel} and Steven Guan",

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year = "2022",

doi = "10.4018/IJDST.296246",

language = "English",

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journal = "International Journal of Distributed Systems and Technologies",

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AU - Chang, Victor

AU - Kandadai, Keerthi

AU - Xu, Qianwen Ariel

AU - Guan, Steven

PY - 2022

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AB - This paper describes how to develop diabetes diagnosis through the combined use of the support vector machine, the decision tree, naive bayes, k-nearest, and finally, random forest (RF) algorithms. These methods are useful to predict diabetes jointly. The appropriateness of ML-depended techniques to tackle this issue has been revealed. This diabetes diagnosis system using machine-learning algorithms is used to review papers. This project was based on developing Python-based code for machine learning algorithms to perform large scale diabetes analysis. The hardware requirement of machine learning is RAM that is 128 GB DDR4 2133 MHz and 2 TB Hard Disk and needs 512 GB SSD. One standard library is NumPy, which is used to support multi-dimensional arrays objects, various components, and matrices. The random forest prediction representing the pictorial visualization of the model and the accuracy for the data analysis using the random forest is 76%.

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KW - Random Forest Prediction

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Development of a Diabetes Diagnosis System Using Machine Learning Algorithms

Abstract

Keywords

UN SDGs

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