Improved accuracy and less fault prediction errors via modified sequential minimal optimization algorithm

The benefits and opportunities offered by cloud computing are among the fastest-growing technologies in the computer industry. Additionally, it addresses the difficulties and issues that make more users more likely to accept and use the technology. The proposed research comprised of machine learning...

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Bibliographic Details
Published in:PloS one 2023-04, Vol.18 (4), p.e0284209-e0284209
Main Authors: Asim Shahid, Muhammad, Alam, Muhammad Mansoor, Mohd Su'ud, Mazliham
Format: Article
Language:English
Subjects:
Algorithms
Artificial intelligence
Bayes Theorem
Classification
Classifiers
Cloud computing
Complexity
Computer and Information Sciences
Computer hardware industry
Computer industry
Computers
Datasets
Engineering and Technology
Errors
Evaluation
Failure
Fault diagnosis
Forecasts and trends
Internet
Lagrange multiplier
Machine Learning
Mathematical optimization
Optimization
Physical Sciences
Predictions
Product reviews
Random Forest
Research and Analysis Methods
Research methodology
Software services
Support Vector Machine
Support vector machines
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Summary:The benefits and opportunities offered by cloud computing are among the fastest-growing technologies in the computer industry. Additionally, it addresses the difficulties and issues that make more users more likely to accept and use the technology. The proposed research comprised of machine learning (ML) algorithms is Naïve Bayes (NB), Library Support Vector Machine (LibSVM), Multinomial Logistic Regression (MLR), Sequential Minimal Optimization (SMO), K Nearest Neighbor (KNN), and Random Forest (RF) to compare the classifier gives better results in accuracy and less fault prediction. In this research, the secondary data results (CPU-Mem Mono) give the highest percentage of accuracy and less fault prediction on the NB classifier in terms of 80/20 (77.01%), 70/30 (76.05%), and 5 folds cross-validation (74.88%), and (CPU-Mem Multi) in terms of 80/20 (89.72%), 70/30 (90.28%), and 5 folds cross-validation (92.83%). Furthermore, on (HDD Mono) the SMO classifier gives the highest percentage of accuracy and less fault prediction fault in terms of 80/20 (87.72%), 70/30 (89.41%), and 5 folds cross-validation (88.38%), and (HDD-Multi) in terms of 80/20 (93.64%), 70/30 (90.91%), and 5 folds cross-validation (88.20%). Whereas, primary data results found RF classifier gives the highest percentage of accuracy and less fault prediction in terms of 80/20 (97.14%), 70/30 (96.19%), and 5 folds cross-validation (95.85%) in the primary data results, but the algorithm complexity (0.17 seconds) is not good. In terms of 80/20 (95.71%), 70/30 (95.71%), and 5 folds cross-validation (95.71%), SMO has the second highest accuracy and less fault prediction, but the algorithm complexity is good (0.3 seconds). The difference in accuracy and less fault prediction between RF and SMO is only (.13%), and the difference in time complexity is (14 seconds). We have decided that we will modify SMO. Finally, the Modified Sequential Minimal Optimization (MSMO) Algorithm method has been proposed to get the highest accuracy & less fault prediction errors in terms of 80/20 (96.42%), 70/30 (96.42%), & 5 fold cross validation (96.50%).
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0284209