Multiobjective optimization of solar-powered irrigation system with fuzzy type-2 noise modelling
Design optimization has been commonly practiced for many years across various engineering disciplines. Optimization per se is becoming a crucial element in industrial applications involving sustainable alternative energy systems. During the design of such systems, the engineer/decision maker would o...
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2016
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my.utp.eprints.306872022-03-25T07:15:05Z Multiobjective optimization of solar-powered irrigation system with fuzzy type-2 noise modelling Ganesan, T. Vasant, P. Elamvazuthi, I. Design optimization has been commonly practiced for many years across various engineering disciplines. Optimization per se is becoming a crucial element in industrial applications involving sustainable alternative energy systems. During the design of such systems, the engineer/decision maker would often encounter noise factors (e.g. solar insolation and ambient temperature fluctuations) when their system interacts with the environment. Therefore, successful modelling and optimization procedures would require a framework that encompasses all these uncertainty features and solves the problem at hand with reasonable accuracy. In this chapter, the sizing and design optimization of the solar powered irrigation system was considered. This problem is multivariate, noisy, nonlinear and multiobjective. This design problem was tackled by first using the Fuzzy Type II approach to model the noise factors. Consequently, the Bacterial Foraging Algorithm (BFA) (in the context of a weighted sum framework) was employed to solve this multiobjective fuzzy design problem. This method was then used to construct the approximate Pareto frontier as well as to identify the best solution option in a fuzzy setting. Comprehensive analyses and discussions were performed on the generated numerical results with respect to the implemented solution methods. © 2017, IGI Global. IGI Global 2016 Book NonPeerReviewed https://www.scopus.com/inward/record.uri?eid=2-s2.0-85016345150&doi=10.4018%2f978-1-5225-0914-1.ch008&partnerID=40&md5=806fca27f34ba512c91b51ff598015cd Ganesan, T. and Vasant, P. and Elamvazuthi, I. (2016) Multiobjective optimization of solar-powered irrigation system with fuzzy type-2 noise modelling. IGI Global, pp. 189-214. http://eprints.utp.edu.my/30687/ |
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Design optimization has been commonly practiced for many years across various engineering disciplines. Optimization per se is becoming a crucial element in industrial applications involving sustainable alternative energy systems. During the design of such systems, the engineer/decision maker would often encounter noise factors (e.g. solar insolation and ambient temperature fluctuations) when their system interacts with the environment. Therefore, successful modelling and optimization procedures would require a framework that encompasses all these uncertainty features and solves the problem at hand with reasonable accuracy. In this chapter, the sizing and design optimization of the solar powered irrigation system was considered. This problem is multivariate, noisy, nonlinear and multiobjective. This design problem was tackled by first using the Fuzzy Type II approach to model the noise factors. Consequently, the Bacterial Foraging Algorithm (BFA) (in the context of a weighted sum framework) was employed to solve this multiobjective fuzzy design problem. This method was then used to construct the approximate Pareto frontier as well as to identify the best solution option in a fuzzy setting. Comprehensive analyses and discussions were performed on the generated numerical results with respect to the implemented solution methods. © 2017, IGI Global. |
format |
Book |
author |
Ganesan, T. Vasant, P. Elamvazuthi, I. |
spellingShingle |
Ganesan, T. Vasant, P. Elamvazuthi, I. Multiobjective optimization of solar-powered irrigation system with fuzzy type-2 noise modelling |
author_facet |
Ganesan, T. Vasant, P. Elamvazuthi, I. |
author_sort |
Ganesan, T. |
title |
Multiobjective optimization of solar-powered irrigation system with fuzzy type-2 noise modelling |
title_short |
Multiobjective optimization of solar-powered irrigation system with fuzzy type-2 noise modelling |
title_full |
Multiobjective optimization of solar-powered irrigation system with fuzzy type-2 noise modelling |
title_fullStr |
Multiobjective optimization of solar-powered irrigation system with fuzzy type-2 noise modelling |
title_full_unstemmed |
Multiobjective optimization of solar-powered irrigation system with fuzzy type-2 noise modelling |
title_sort |
multiobjective optimization of solar-powered irrigation system with fuzzy type-2 noise modelling |
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IGI Global |
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2016 |
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https://www.scopus.com/inward/record.uri?eid=2-s2.0-85016345150&doi=10.4018%2f978-1-5225-0914-1.ch008&partnerID=40&md5=806fca27f34ba512c91b51ff598015cd http://eprints.utp.edu.my/30687/ |
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