Approaches of fuzzy systems applied to an AGV dispatching system in a FMS
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- 作者:V. F. Caridá ; O. Morandin Jr. ; C. C. M. Tuma
- 关键词:Automated guided vehicles ; AGV dispatching ; Fuzzy system ; Multi ; attribute ; FMS ; Makespan minimization
- 刊名:The International Journal of Advanced Manufacturing Technology
- 出版年:2015
- 出版时间:July 2015
- 年:2015
- 卷:79
- 期:1-4
- 页码:615-625
- 全文大小:910 KB
- 参考文献:1.Joshi SB, Smith JS (1994) Computer control of flexible manufacturing systems: research and development. Chapman & Hall, p 427
2.Evers JJM, Koppers SAJ (1996) Automated guided vehicle traffic control at a container terminal. Transp Res A Policy Pract 30(1):21-4View Article
3.Qiu L, Hsu W, Huang S, Wang H (2002) Scheduling and routing algorithms for AGVs: a survey. Int J Prod Res 40(3)
4.Ye R, Hsu WJ, Vee VY (2000) Distributed routing and simulation of automated guided vehicles. In: IEEE Region 10 Annual International Conference, Malaysia
5.Seifert RW, Kay MG (1995) Evaluation of AGV routing strategies using hierarchical simulation. In: Winter Simulation Conference, Arlington, USA
6.Le-Anh T, De Koster MBM (2006) A review of design and control of automated guided vehicle systems. Eur J Oper Res 171(1):1-3View Article MATH
7.Vis IFA (2006) Survey of research in the design and control of automated guided vehicle systems. Eur J Oper Res 170(3):677-09View Article MATH MathSciNet
8.Egbelu PJ (1987) Pull versus push strategy for automated guided vehicle load movement in a batch manufacturing system. J Manuf Syst 6(3):209-21View Article
9.Bartholdi JJ III, Platzman LK (1989) Decentralized control of automated guided vehicles on a simple loop. IIE Trans (Inst Ind Eng) 21(1):76-1
10.Han MH, Mcginnis LF (1989) Control material handling transporter in automated manufacturing. IIE Trans (Inst Ind Eng) 21(2):184-90
11.Taghaboni F (1989) Scheduling and control of manufacturing systems with critical material handling. Ph. D. Thesis -Purdue University, West Lafayette, Indiana
12.Kim SH, Hwang H (199) Adaptive dispatching algorithm for automated guided vehicles based on an evolutionary process. Int J Prod Econ 60
13.Tan KK, Tang KZ (2000) Simulation of an evolutionary tuned fuzzy dispatching system for automated guided vehicles. In: Winter Simulation Conference, Orlando, USA
14.Jeong BH, Randhawa SU (2001) A multi-attribute dispatching rule for automated guided vehicle systems. Int J Prod Res 39(13):2817-832View Article MATH
15.Benincasa AX, Morandin O Jr., Kato ERR (2003) Reactive fuzzy dispatching rule for automated guided vehicles. Syst Man Cybern 5
16.Umashankar N, Karthik VN (2006) Multi-criteria intelligent dispatching control of automated guided vehicles in FMS. In: Ieee Conference on Cybernetics and Intelligent Systems, Thailand
17.Naso D, Turchiano B (2005) Multicriteria meta-heuristics for AGV dispatching control based on computational intelligence. IEEE Trans Syst Man Cybern Part B Cybern 35(2)
18.Hidehiko Y (2008) Addition and deletion of agent memories to realize autonomous decentralized manufacturing systems. In: Lecture notes in computer science, Wroclaw, Poland
19.Smolic-Rocak N, Bogdan S, Kovacic Z, Petrovic T (2010) Time windows based dynamic routing in multi-AGV systems. IEEE Trans Autom Sci Eng 7(1)
20.Chiba R, Arai T, Ota J (2010) Integrated design for automated guided vehicle systems using cooperative co-evolution. Adv Robot 24(1-):25-5View Article
21.Pedrycz W (1996) Fuzzy modelling: paradigms and practice. Kluwer, DordrechtView Article MATH
22.Dumitrescu D, Lazzerini B, Jair L (2000) Fuzzy sets and their application to clustering and training. Int. Series on Computational Intelligence, CBC Press
23.Takagi T, Sugeno M (1985) Fuzzy identification of systems and its application to modeling and control. IEEE Trans Syst Man Cybern 116-32
24.Buckley JJ, Hayashi Y (1993) Numerical relationships between neural networks, continuous functions, and fuzzy systems. Fuzzy Sets Syst 60:1-View Article MathSciNet
25.Driankov D, Hellendoorn H, Reinfrank M (1993) An introduction to fuzzy control. Springer, BerlinView Article MATH
26.Jang JSR (1993) ANFIS: adaptive-network-based fuzzy inference system. IEEE Trans Syst Man Cybern 23:665-85View Article
27.Wang P et al (1995) Constructing fuzzy systems. Proc. VI IFSA Congr. San Paulo
28.Wang LX, Mendel JM (1992) Fuzzy basis functions, universal approximation and orthogonal least-squares learning. IEEE Trans Neural Netw 3:807-14View Article
29.Wang LX (1994) Adaptive fuzzy systems and control design and stability analysis. PTR Prentice-Hall, Englewood Cliffs
30.Zeng X-J, Singh MG (1994) Approximate theory of fuzzy systems—SISO case. IEEE Trans Fuzzy Syst 2:162-76View Article
31.Wang L (2003) The WM method completed: a flexible fuzzy system approach to data mining. IEEE Int Conf Fuzzy Syst 11:768-82View Article
32.Chen Y, Yang B, Abraham A, Peng L (2007) Automatic design of hierarchical Takagi–Sugeno type fuzzy systems using evolutionary algorithms. IEEE Trans Fuzzy Syst 15(3):385-97View Article MATH
33.Gedeon TD, Wong KW, Tikk D (2001) Constructing hierarquical fuzzy rules bases for classification. The 10th IEEE International Fuzzy Systems Conference, vol. 3
34.Sugeno M, Yasukawa T (1993) A fuzzy-logic-based approach to qualitative modeling. IEEE - 作者单位:V. F. Caridá (1)
O. Morandin Jr. (1)
C. C. M. Tuma (1)
1. Department of Computer Science, Federal University of S?o Carlos, Rodovia Washington Luis, Km 235, 13565-905, S?o Carlos, SP, Brazil - 刊物类别:Engineering
- 刊物主题:Industrial and Production Engineering
Production and Logistics
Mechanical Engineering
Computer-Aided Engineering and Design - 出版者:Springer London
- ISSN:1433-3015
文摘
Excellence in manufacturing systems has been recognized as one of the main factors behind the success of industrial companies or production companies. New technology for manufacturing processes plays a significant role in this process. Achieving the potential of technological innovations in production, however, requires a wide range of management, as well as engineering issues related to the system. The handling capacity of advanced materials is essential because without this ability of providing the material needed for the proper workstation at the right time and in the right amount, the whole plant will become “bogged down.-This makes it less efficient and thus produces less profit, and/or it operates at higher costs. This paper proposes two approaches for the dispatching of AGV (automated guided vehicle) using systems fuzzy. The first use hierarchical fuzzy rule-based model building in which the main feature is to make the base of fuzzy rules is smaller and simpler but with high coverage and interpretability. The second use adaptive genetic fuzzy system with simple prediction in which the main feature is to increase the sensitivity of the system about the variables. Both approaches using multiple attributes and having the objective decrease the makespan in a FMS (flexible manufacturing system).