2024_Optimized Practical Byzantine Fault Tolerance Algorithm Using Grouping Approach For Consortium
| Format: | General Document |
|---|
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| building | INTELEK Repository |
| collection | Online Access |
| collectionurl | https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection3 |
| copyright | Copyright©PWB2025 |
| country | Malaysia |
| date | 2024-10-21 01:01 |
| format | General Document |
| id | 17249 |
| institution | UniSZA |
| originalfilename | 17249_7113ea17c1d895f.pdf |
| person | Nurul Jannah Binti Mohamad Yusoff |
| recordtype | oai_dc |
| resourceurl | https://intelek.unisza.edu.my/intelek/pages/view.php?ref=17249 |
| sourcemedia | Server storage Scanned document |
| spelling | 17249 https://intelek.unisza.edu.my/intelek/pages/view.php?ref=17249 https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection3 General Document Malaysia Library Staff (Top Management) Library Staff (Management) Library Staff (Support) Terengganu Faculty of Informatics & Computing English application/pdf 1.7 Microsoft® Word 2019 Server storage Scanned document UniSZA Private Access UniSZA Copyright©PWB2025 81 Blockchain UniSZA Dissertations-Academic Recent years have witnessed a transformative shift in the field of heart disease prediction, driven by the widespread adoption of advanced machine learning and data analytics techniques. Heart disease remains a common global health dilemma, with substantial implications for both morbidity and mortality across the world. The fact that nearly 12 million lives are lost yearly emphasizes the central challenge facing healthcare professionals. In most countries, a shortage of cardiovascular specialists endures, accompanied by a troubling rate of incorrectly diagnosed cases. To tackle these challenges, it is crucial to establish a precise and efficient early-stage prediction model for detecting heart diseases in patients. This is further supported by the utilization of analytical instruments aimed at enhancing the effectiveness of the clinical decision-making process. Presently, previous research tends to lack comprehensive investigations, as most research leans towards using single classifiers and may not encompass the full spectrum of available features in their experiments leading to lower accuracy for the prediction of heart disease. In addressing this issue, the research aims to explore the effectiveness of an ensemble stacking classification method in combination with a feature selection technique. This research tends to bridge this gap by employing the UCI dataset comprising 303 records and 13 attributes, aiming to explore the efficacy of the selected method. Specifically, a hybrid approach feature selection method was employed to combine chi-squared and analysis of variance (ANOVA), aimed to filter out the most crucial features for subsequent evaluation with chosen classifiers. Ten base classifiers are assessed including logistic regression (LR), random forest (RF), k-nearest neighbor (KNN), decision tree (DT), naïve bayes (NB), support vector classifier (SVC), extra gradient boosting (XGB), multi-layer perceptron (MLP), stochastic gradient descent (SGD), and extra tree classifier (ETC). In comparison, the meta-model classifiers consisting of LR, SVC, MLP, and NB each displaying different levels of accuracy are tested with the selected features from chi-squared and ANOVA. As a result, 93.44% accuracy achieved by naïve bayes stands out as the most promising outcome, surpassing individual classifiers. The result distinctly showcases the strength of ensemble techniques and hybrid feature selection in enhancing the accuracy of heart disease prediction. In conclusion, this study investigates the efficiency of combining an ensemble stacking method with a feature selection technique to predict heart disease. By using a hybrid feature selection approach that incorporates chi-squared and ANOVA, essential features are effectively pinpointed for subsequent evaluation with chosen classifiers. This research sets the stage for the creation of more precise and dependable heart disease prediction tools, with the potential to enhance clinical decision-making and ultimately benefit patient outcomes. Nurul Jannah Binti Mohamad Yusoff Distributed Algorithms Fault-Tolerant Computing Computer Networks — Performance Algorithms — Optimization Practical Byzantine Fault Tolerance (PBFT) Optimized PBFT Blockchain Consortium Blockchain Distributed Systems Consensus Mechanism Network Scalability Latency Reduction Performance Optimization 2024_Optimized Practical Byzantine Fault Tolerance Algorithm Using Grouping Approach For Consortium 2024-10-21 01:01 uuid:3325178C-09F7-4721-85C0-B9EFD9793BE3 17249_7113ea17c1d895f.pdf Thesis |
| spellingShingle | 2024_Optimized Practical Byzantine Fault Tolerance Algorithm Using Grouping Approach For Consortium |
| state | Terengganu |
| subject | Blockchain Dissertations-Academic Distributed Algorithms Fault-Tolerant Computing Computer Networks — Performance Algorithms — Optimization |
| summary | Recent years have witnessed a transformative shift in the field of heart disease prediction, driven by the widespread adoption of advanced machine learning and data analytics techniques. Heart disease remains a common global health dilemma, with substantial implications for both morbidity and mortality across the world. The fact that nearly 12 million lives are lost yearly emphasizes the central challenge facing healthcare professionals. In most countries, a shortage of cardiovascular specialists endures, accompanied by a troubling rate of incorrectly diagnosed cases. To tackle these challenges, it is crucial to establish a precise and efficient early-stage prediction model for detecting heart diseases in patients. This is further supported by the utilization of analytical instruments aimed at enhancing the effectiveness of the clinical decision-making process. Presently, previous research tends to lack comprehensive investigations, as most research leans towards using single classifiers and may not encompass the full spectrum of available features in their experiments leading to lower accuracy for the prediction of heart disease. In addressing this issue, the research aims to explore the effectiveness of an ensemble stacking classification method in combination with a feature selection technique. This research tends to bridge this gap by employing the UCI dataset comprising 303 records and 13 attributes, aiming to explore the efficacy of the selected method. Specifically, a hybrid approach feature selection method was employed to combine chi-squared and analysis of variance (ANOVA), aimed to filter out the most crucial features for subsequent evaluation with chosen classifiers. Ten base classifiers are assessed including logistic regression (LR), random forest (RF), k-nearest neighbor (KNN), decision tree (DT), naïve bayes (NB), support vector classifier (SVC), extra gradient boosting (XGB), multi-layer perceptron (MLP), stochastic gradient descent (SGD), and extra tree classifier (ETC). In comparison, the meta-model classifiers consisting of LR, SVC, MLP, and NB each displaying different levels of accuracy are tested with the selected features from chi-squared and ANOVA. As a result, 93.44% accuracy achieved by naïve bayes stands out as the most promising outcome, surpassing individual classifiers. The result distinctly showcases the strength of ensemble techniques and hybrid feature selection in enhancing the accuracy of heart disease prediction. In conclusion, this study investigates the efficiency of combining an ensemble stacking method with a feature selection technique to predict heart disease. By using a hybrid feature selection approach that incorporates chi-squared and ANOVA, essential features are effectively pinpointed for subsequent evaluation with chosen classifiers. This research sets the stage for the creation of more precise and dependable heart disease prediction tools, with the potential to enhance clinical decision-making and ultimately benefit patient outcomes. |
| title | 2024_Optimized Practical Byzantine Fault Tolerance Algorithm Using Grouping Approach For Consortium |
| title_full | 2024_Optimized Practical Byzantine Fault Tolerance Algorithm Using Grouping Approach For Consortium |
| title_fullStr | 2024_Optimized Practical Byzantine Fault Tolerance Algorithm Using Grouping Approach For Consortium |
| title_full_unstemmed | 2024_Optimized Practical Byzantine Fault Tolerance Algorithm Using Grouping Approach For Consortium |
| title_short | 2024_Optimized Practical Byzantine Fault Tolerance Algorithm Using Grouping Approach For Consortium |
| title_sort | 2024_optimized practical byzantine fault tolerance algorithm using grouping approach for consortium |