Optimization of nonlinear temperature gradient on eigenfrequency using genetic algorithm for reinforced concrete bridge structural health

Structural damage detection, based on global dynamic parameters, has received considerable attention from civil engineering and even by the local communities. The former sector is facing problems on providing structural integrity to its actual bridge construction due to climate change. Changes in th...

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Main Authors: Concepcion, Ronnie S., Ilagan, Lorena C., Valenzuela, Ira C.
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Published: Animo Repository 2020
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Online Access:https://animorepository.dlsu.edu.ph/faculty_research/3365
https://animorepository.dlsu.edu.ph/context/faculty_research/article/4367/type/native/viewcontent/978_3_030_20904_9_11.html
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spelling oai:animorepository.dlsu.edu.ph:faculty_research-43672021-09-06T08:44:15Z Optimization of nonlinear temperature gradient on eigenfrequency using genetic algorithm for reinforced concrete bridge structural health Concepcion, Ronnie S. Ilagan, Lorena C. Valenzuela, Ira C. Structural damage detection, based on global dynamic parameters, has received considerable attention from civil engineering and even by the local communities. The former sector is facing problems on providing structural integrity to its actual bridge construction due to climate change. Changes in the physical properties of structure such as boundary conditions, stiffness, and mass with respect to modal frequency are customarily studied; however, the unobservable factors such as wind force, humidity and, the most important, temperature must be given weight on analysis. In this study, the suitability of combined approach of supervised machine learning principal component analysis (PCA) and the metaheuristic genetic algorithm (GA) in generating the optimum condition for a reinforced concrete bridge was determined. The parameters that were optimized are the bridge and environment temperatures. These parameters were some of the essential bridge structural health parameters as they have impact on the boundary conditions and properties of materials. This entails that the developed model involves eigenfrequencies as function of temperatures only, which is a minimal parameter approach. The system selected the 50 fittest individuals based on the fitness score and then proceeded to the recombination process. The mutation with rate of 0.01 was applied to test if the solution is the global one. When the iterations had reached the required numbers of generation, the system stopped and gave the optimum condition for a bridge. The GA results showed that the optimum condition for a reinforced concrete bridge needs bridge temperature of 9.578 °C and environment temperature of −8.571 °C. Aside from these temperature values, the bridge is vulnerable to breakage or any damage condition. © Springer Nature Switzerland AG 2020. 2020-01-01T08:00:00Z text text/html https://animorepository.dlsu.edu.ph/faculty_research/3365 info:doi/10.1007/978-3-030-20904-9_11 https://animorepository.dlsu.edu.ph/context/faculty_research/article/4367/type/native/viewcontent/978_3_030_20904_9_11.html Faculty Research Work Animo Repository Concrete bridges—Foundations and piers Genetic algorithms Civil Engineering Manufacturing
institution De La Salle University
building De La Salle University Library
continent Asia
country Philippines
Philippines
content_provider De La Salle University Library
collection DLSU Institutional Repository
topic Concrete bridges—Foundations and piers
Genetic algorithms
Civil Engineering
Manufacturing
spellingShingle Concrete bridges—Foundations and piers
Genetic algorithms
Civil Engineering
Manufacturing
Concepcion, Ronnie S.
Ilagan, Lorena C.
Valenzuela, Ira C.
Optimization of nonlinear temperature gradient on eigenfrequency using genetic algorithm for reinforced concrete bridge structural health
description Structural damage detection, based on global dynamic parameters, has received considerable attention from civil engineering and even by the local communities. The former sector is facing problems on providing structural integrity to its actual bridge construction due to climate change. Changes in the physical properties of structure such as boundary conditions, stiffness, and mass with respect to modal frequency are customarily studied; however, the unobservable factors such as wind force, humidity and, the most important, temperature must be given weight on analysis. In this study, the suitability of combined approach of supervised machine learning principal component analysis (PCA) and the metaheuristic genetic algorithm (GA) in generating the optimum condition for a reinforced concrete bridge was determined. The parameters that were optimized are the bridge and environment temperatures. These parameters were some of the essential bridge structural health parameters as they have impact on the boundary conditions and properties of materials. This entails that the developed model involves eigenfrequencies as function of temperatures only, which is a minimal parameter approach. The system selected the 50 fittest individuals based on the fitness score and then proceeded to the recombination process. The mutation with rate of 0.01 was applied to test if the solution is the global one. When the iterations had reached the required numbers of generation, the system stopped and gave the optimum condition for a bridge. The GA results showed that the optimum condition for a reinforced concrete bridge needs bridge temperature of 9.578 °C and environment temperature of −8.571 °C. Aside from these temperature values, the bridge is vulnerable to breakage or any damage condition. © Springer Nature Switzerland AG 2020.
format text
author Concepcion, Ronnie S.
Ilagan, Lorena C.
Valenzuela, Ira C.
author_facet Concepcion, Ronnie S.
Ilagan, Lorena C.
Valenzuela, Ira C.
author_sort Concepcion, Ronnie S.
title Optimization of nonlinear temperature gradient on eigenfrequency using genetic algorithm for reinforced concrete bridge structural health
title_short Optimization of nonlinear temperature gradient on eigenfrequency using genetic algorithm for reinforced concrete bridge structural health
title_full Optimization of nonlinear temperature gradient on eigenfrequency using genetic algorithm for reinforced concrete bridge structural health
title_fullStr Optimization of nonlinear temperature gradient on eigenfrequency using genetic algorithm for reinforced concrete bridge structural health
title_full_unstemmed Optimization of nonlinear temperature gradient on eigenfrequency using genetic algorithm for reinforced concrete bridge structural health
title_sort optimization of nonlinear temperature gradient on eigenfrequency using genetic algorithm for reinforced concrete bridge structural health
publisher Animo Repository
publishDate 2020
url https://animorepository.dlsu.edu.ph/faculty_research/3365
https://animorepository.dlsu.edu.ph/context/faculty_research/article/4367/type/native/viewcontent/978_3_030_20904_9_11.html
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