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Karthikeyan, T.
- Gene Biclustering On Large Datasets Using Fuzzy C-means Clustering
Abstract Views :138 |
PDF Views:1
Authors
Affiliations
1 Department of Computer Science and Engineering, HKBK College of Engineering, IN
2 Department of Computer Science and Engineering, Jain University, IN
3 Department of Computer Science and Engineering, Presidency University, IN
4 Department of Electronics and Telecommunications Engineering, University of Technology and Applied Sciences, OM
1 Department of Computer Science and Engineering, HKBK College of Engineering, IN
2 Department of Computer Science and Engineering, Jain University, IN
3 Department of Computer Science and Engineering, Presidency University, IN
4 Department of Electronics and Telecommunications Engineering, University of Technology and Applied Sciences, OM
Source
ICTACT Journal on Soft Computing, Vol 12, No 2 (2022), Pagination: 2578-2582Abstract
The current study employs biclustering to alleviate some of the drawbacks associated with gene expression data grouping. Different biclustering algorithms are used in this study to detect unique gene activity in various contexts and reduce the duplication of broad gene information. Furthermore, machine learning or heuristic algorithms have become widely utilised for biclustering due to their suitability in problems where populations of potential solutions allow examination of a larger percentage of the research area. To begin with, gene expression data biclusters frequently contain data that is the same under a variety of different situations of gene expression. Therefore, the biclustering technique is particularly effective if the matrix lines and columns are merged immediately. Submatrices can be identified using the Large Average Sub matrix. A Fuzzy C-Means algorithm is also used to ensure that the sub-matrix can be expanded to include more rows and columns for further analysis. The sub-matrices and component precision and strength are factored into the system design. It uses biclustering techniques to differentiate gene expression information. On the Garber dataset, the simulation is run in Java. Using the average match score for non-overlapping modules, the influence of noise on overlapping modules using constant bicluster and additive bicluster, and the overall run duration, the study is assessed.Keywords
Heuristic Algorithm, Gene Expression, Data Biclusters, Fuzzy C-MeansReferences
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- Hybrid Neuro-fuzzy-genetic Algorithms for Optimal Control of Autonomous Systems
Abstract Views :23 |
PDF Views:2
Authors
Affiliations
1 Department of Mechanical Engineering, Theni Kammavar Sangam College of Technology, IN
2 Department of Information Technology, Siddhant College of Engineering, IN
3 Department of Information Technology, University College of Technology and Applied Sciences - Salalah, OM
4 Indian Institute of Information Technology Kalyani, IN
1 Department of Mechanical Engineering, Theni Kammavar Sangam College of Technology, IN
2 Department of Information Technology, Siddhant College of Engineering, IN
3 Department of Information Technology, University College of Technology and Applied Sciences - Salalah, OM
4 Indian Institute of Information Technology Kalyani, IN
Source
ICTACT Journal on Soft Computing, Vol 13, No 4 (2023), Pagination: 3015-3020Abstract
In recent years, there has been an increasing demand for efficient and robust control algorithms to optimize the performance of autonomous systems. Traditional control techniques often struggle to handle the complexity and uncertainty associated with such systems. To address these challenges, hybrid neuro-fuzzy-genetic algorithms have emerged as a promising approach. This paper presents a comprehensive review of the application of hybrid neuro-fuzzy-genetic algorithms for optimal control of autonomous systems. The proposed algorithms combine the strengths of neural networks, fuzzy logic, and genetic algorithms to achieve adaptive and optimal control in real-time scenarios. The neuro-fuzzy component provides the ability to model and handle complex and uncertain systems, while the genetic algorithm component facilitates the optimization of control parameters. The combination of these techniques enables autonomous systems to adapt and optimize their control strategies based on changing environments and objectives. The paper discusses the underlying principles of hybrid neuro-fuzzy-genetic algorithms, their advantages, and challenges. It also provides a review of the state-of-the-art research in this field, highlighting successful applications and potential future directions. Overall, the integration of neuro-fuzzy-genetic algorithms in autonomous systems holds great promise for achieving optimal control in various domains, including robotics, aerospace, and autonomous vehicles.Keywords
Hybrid Algorithms, Neuro-Fuzzy-Genetic Algorithms, Optimal Control, Autonomous Systems, Neural Networks, Fuzzy Logic, Genetic Algorithms, Real-Time Control, Adaptive Control, Uncertainty, Robotics, Aerospace, Autonomous Vehicles.References
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