3D facility layout problem

Facility layout aims to arrange a set of facilities in a site. The main objective function is to minimize the total material handling cost under production-derived constraints. This problem has received much attention during the past decades. However, these works have mainly focused on solving a 2D...

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Veröffentlicht in:	Journal of intelligent manufacturing 2021-04, Vol.32 (4), p.1065-1090
Hauptverfasser:	Besbes, Mariem, Zolghadri, Marc, Costa Affonso, Roberta, Masmoudi, Faouzi, Haddar, Mohamed
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Business and Management Control Convergence Distance measurement Engineering Sciences Euclidean geometry Facilities management Genetic algorithms Layouts Machines Manufacturing Materials handling Measurement techniques Mechatronics Objective function Particle swarm optimization Problem solving Processes Production Robotics Shortest-path problems Workshops
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container_title	Journal of intelligent manufacturing
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creator	Besbes, Mariem Zolghadri, Marc Costa Affonso, Roberta Masmoudi, Faouzi Haddar, Mohamed
description	Facility layout aims to arrange a set of facilities in a site. The main objective function is to minimize the total material handling cost under production-derived constraints. This problem has received much attention during the past decades. However, these works have mainly focused on solving a 2D layout problem, dealing with the footprints of pieces of equipment. The obtained results have been then adapted to the real spatial constraints of a workshop. This research work looks to take account of spatial constraints within a 3D space from the very first steps of problem solving. The authors use a approach by combining a genetic algorithm with A, 〈GA,A〉 research. The genetic algorithm generates possible arrangements and A* finds the shortest paths that products must travel in a restricted 3D space. The application allows to converge to a layout minimizing the total material handling cost. This approach is illustrated by its application on an example inspired by a valve assembly workshop in Tunisia and the results are discussed from two points of view. The first one consists in comparing the effect of the choice of the distance measurement technique on the handling cost. For this purpose, the results of the application of 〈GA,A〉 are compared with those obtained by combining the genetic algorithm and two of the most commonly used distance measurements in the literature of the discipline, namely the Euclidean distance, 〈GA,Euclidean〉, and the rectilinear distance, 〈GA,rectilinear〉. Our results show that the proposed approach offers better results than those of 〈GA,rectilinear〉 whereas they are not as good as those obtained by the 〈GA,Euclidean〉 approach. The effectiveness of the 〈GA,A〉 approach is then studied from the perspective of the effect of the algorithm used for the generation of candidate arrangements. The final results obtained from the application of 〈GA,A〉 are then compared with those of the approach combining particle swarm optimization and A, 〈PSO,A〉. This comparison shows that the 〈GA,A〉 approach obtains better results. Nevertheless, its convergence speed is lower than that of 〈PSO,A*〉. The paper ends with some conclusions and perspectives.
doi_str_mv	10.1007/s10845-020-01603-z
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The main objective function is to minimize the total material handling cost under production-derived constraints. This problem has received much attention during the past decades. However, these works have mainly focused on solving a 2D layout problem, dealing with the footprints of pieces of equipment. The obtained results have been then adapted to the real spatial constraints of a workshop. This research work looks to take account of spatial constraints within a 3D space from the very first steps of problem solving. The authors use a approach by combining a genetic algorithm with A, 〈GA,A〉 research. The genetic algorithm generates possible arrangements and A* finds the shortest paths that products must travel in a restricted 3D space. The application allows to converge to a layout minimizing the total material handling cost. This approach is illustrated by its application on an example inspired by a valve assembly workshop in Tunisia and the results are discussed from two points of view. The first one consists in comparing the effect of the choice of the distance measurement technique on the handling cost. For this purpose, the results of the application of 〈GA,A〉 are compared with those obtained by combining the genetic algorithm and two of the most commonly used distance measurements in the literature of the discipline, namely the Euclidean distance, 〈GA,Euclidean〉, and the rectilinear distance, 〈GA,rectilinear〉. Our results show that the proposed approach offers better results than those of 〈GA,rectilinear〉 whereas they are not as good as those obtained by the 〈GA,Euclidean〉 approach. The effectiveness of the 〈GA,A〉 approach is then studied from the perspective of the effect of the algorithm used for the generation of candidate arrangements. The final results obtained from the application of 〈GA,A〉 are then compared with those of the approach combining particle swarm optimization and A, 〈PSO,A〉. This comparison shows that the 〈GA,A〉 approach obtains better results. Nevertheless, its convergence speed is lower than that of 〈PSO,A〉. 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The main objective function is to minimize the total material handling cost under production-derived constraints. This problem has received much attention during the past decades. However, these works have mainly focused on solving a 2D layout problem, dealing with the footprints of pieces of equipment. The obtained results have been then adapted to the real spatial constraints of a workshop. This research work looks to take account of spatial constraints within a 3D space from the very first steps of problem solving. The authors use a approach by combining a genetic algorithm with A, 〈GA,A〉 research. The genetic algorithm generates possible arrangements and A finds the shortest paths that products must travel in a restricted 3D space. The application allows to converge to a layout minimizing the total material handling cost. This approach is illustrated by its application on an example inspired by a valve assembly workshop in Tunisia and the results are discussed from two points of view. The first one consists in comparing the effect of the choice of the distance measurement technique on the handling cost. For this purpose, the results of the application of 〈GA,A〉 are compared with those obtained by combining the genetic algorithm and two of the most commonly used distance measurements in the literature of the discipline, namely the Euclidean distance, 〈GA,Euclidean〉, and the rectilinear distance, 〈GA,rectilinear〉. Our results show that the proposed approach offers better results than those of 〈GA,rectilinear〉 whereas they are not as good as those obtained by the 〈GA,Euclidean〉 approach. The effectiveness of the 〈GA,A〉 approach is then studied from the perspective of the effect of the algorithm used for the generation of candidate arrangements. The final results obtained from the application of 〈GA,A〉 are then compared with those of the approach combining particle swarm optimization and A, 〈PSO,A〉. This comparison shows that the 〈GA,A〉 approach obtains better results. Nevertheless, its convergence speed is lower than that of 〈PSO,A〉. 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Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Besbes, Mariem</au><au>Zolghadri, Marc</au><au>Costa Affonso, Roberta</au><au>Masmoudi, Faouzi</au><au>Haddar, Mohamed</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>3D facility layout problem</atitle><jtitle>Journal of intelligent manufacturing</jtitle><stitle>J Intell Manuf</stitle><date>2021-04-01</date><risdate>2021</risdate><volume>32</volume><issue>4</issue><spage>1065</spage><epage>1090</epage><pages>1065-1090</pages><issn>0956-5515</issn><eissn>1572-8145</eissn><abstract>Facility layout aims to arrange a set of facilities in a site. The main objective function is to minimize the total material handling cost under production-derived constraints. This problem has received much attention during the past decades. However, these works have mainly focused on solving a 2D layout problem, dealing with the footprints of pieces of equipment. The obtained results have been then adapted to the real spatial constraints of a workshop. This research work looks to take account of spatial constraints within a 3D space from the very first steps of problem solving. The authors use a approach by combining a genetic algorithm with A, 〈GA,A〉 research. The genetic algorithm generates possible arrangements and A finds the shortest paths that products must travel in a restricted 3D space. The application allows to converge to a layout minimizing the total material handling cost. This approach is illustrated by its application on an example inspired by a valve assembly workshop in Tunisia and the results are discussed from two points of view. The first one consists in comparing the effect of the choice of the distance measurement technique on the handling cost. For this purpose, the results of the application of 〈GA,A〉 are compared with those obtained by combining the genetic algorithm and two of the most commonly used distance measurements in the literature of the discipline, namely the Euclidean distance, 〈GA,Euclidean〉, and the rectilinear distance, 〈GA,rectilinear〉. Our results show that the proposed approach offers better results than those of 〈GA,rectilinear〉 whereas they are not as good as those obtained by the 〈GA,Euclidean〉 approach. The effectiveness of the 〈GA,A〉 approach is then studied from the perspective of the effect of the algorithm used for the generation of candidate arrangements. The final results obtained from the application of 〈GA,A〉 are then compared with those of the approach combining particle swarm optimization and A, 〈PSO,A〉. This comparison shows that the 〈GA,A〉 approach obtains better results. Nevertheless, its convergence speed is lower than that of 〈PSO,A*〉. The paper ends with some conclusions and perspectives.</abstract><cop>New York</cop><pub>Springer US</pub><doi>10.1007/s10845-020-01603-z</doi><tpages>26</tpages><orcidid>https://orcid.org/0000-0003-2995-0424</orcidid><orcidid>https://orcid.org/0000-0002-0377-2271</orcidid></addata></record>
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subjects	Algorithms Business and Management Control Convergence Distance measurement Engineering Sciences Euclidean geometry Facilities management Genetic algorithms Layouts Machines Manufacturing Materials handling Measurement techniques Mechatronics Objective function Particle swarm optimization Problem solving Processes Production Robotics Shortest-path problems Workshops
title	3D facility layout problem
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