Buradasınız

Anasayfa » Content

TOPLAM ÜRETİM PLANLAMASI PROBLEMİ İÇİN BİR BULANIK HEDEF PROGRAMLAMA YAKLAŞIMI

A FUZZY GOAL PROGRAMMING APPROACH FOR AGGREGATE PRODUCTION PLANNING

Journal Name:

  • Erciyes Üniversitesi İktisadi ve İdari Bilimler Fakültesi Dergisi

Publication Year:

  • 2009

Key Words:

Keywords (Original Language):

Author NameUniversity of AuthorFaculty of Author
Abstract (2. Language): 
The objective of this study is to develop a fuzzy goal programming model for the aggregate production problem. Fuzzy goals and constraints of the model are converted into crisp goals and constraints using their corresponding membership function values. Then the crisp equivalent of the fuzzy model is derived. The goals of the model are to minimize a weighted function of various cost components and achieve a smooth workload on work stations. The approach is illustrated by means of an illustrative problem. The results suggest that this approach is an effective solution strategy and can guide and assist the decision maker for planning periodic production, capacity and inventory.
Bookmark/Search this post with
Abstract (Original Language): 
Bu çalışmanın amacı toplam üretim planlaması problemi için bir bulanık hedef programlama modeli geli tirmektir. Bulank amaçlar ve kısıtlar üyelik fonksiyonları kullanılarak mutlak amaç ve kısıtlara dönü türülmektedir. Daha sonra bulanık modelin denk mutlak modeli olu turulmaktad ır. Modelin amaçlar çe itli maliyet bile enlerinin ağırlıklı bir fonksiyonunu minimum yapmak ve i merkezlerinde düzgün bir i yükü dağılımı gerçekleştirmektir. Yaklaşım bir sayısal örnek problem üzerinde açıklanmaktadır. Sonuçlar, bu yaklaşımın etkin bir çözüm stratejisi olduğunu ve periyodik üretimi, kapasiteyi ve envanteri planlamada karar vericiye yol gösterici ve yardımcı olabileceğini ortaya koymaktadır.
FULL TEXT (PDF): 
PDF icon arastirmax-toplam-uretim-planlamasi-problemi-icin-bir-bulanik-hedef-programlama-yaklasimi.pdf
  • 34
69-90
  • Turkish

REFERENCES

References: 

BAYKASOGLU, A.; (2001), “Moapps 1.0: Aggregate Production Planning
Using the Multiple-Objective Tabu Search”, International Journal of
Production Research, 39, ss. 3685–3702.
BELLMAN, R.E. ve L.A. ZADEH; (1970), “Decision Making in a Fuzzy
Environment”, International Journal of Management Science,
17,ss. 141-164.
BUXEY,G.; (2003), “Strategy not Tactics Drives Aggregate Planning”,
International Journal of Production Economics 85(3), ss. 331–346.
BYRNE, M. D. ve M. A BAKIR.; (1999), “Production Planning Using a
Hybrid Simulation–Analytical Approach” International Journal of
Production Economics, 59, ss. 305–311.
BOWMAN, E. H.; (1956), “Production Scheduling by the Transportation
Method of Linear Programming”, Operations Research, 4, ss. 100–
103
BOWMAN, E. H.; (1963) “Consistency and Optimality in Managerial Decision
Making”, Management Science 9, ss. 310–321.
CHARNES, A. ve W. W. COOPER; (1961), Management Models and
Industrial Application of Linear Programming, Vol. 1, Wiley, New
York, 467s
CHASE, B., N.J. AQU LANO ve F.R. JACOBS; (1998), Production and
Operations Management, Eight Edition, McGraw-Hill,Boston,USA,
880s
CHEN, L. H. ve F. C. TSA ; (2001), “Fuzzy Goal Programming with Different
Importance and Priorities”, European Journal of Operational
Research, 1333, ss. 548-556.
DANTZIG, G. B.; (1955), “Linear Programming Under Uncertainty”,
Management Science, 1, ss. 197–206.
DOBOS, I.; (2003), “Optimal Production–Inventory Strategies for a HMMSType
Reverse Logistics System”, International Journal of
Production Economics 81–82, ss. 351–360
FAH MN A, B., ,L.H.S. LUONG ve R. M. MAR AN; (2006), “Modeling and
Optimization of Aggregate Production Planning - A Genetic
Algorithm Approach” Proceedings of World Academy of Science,
Engineering and Technology, 15, ss. 169-174.
FENG, Y.J.; (1983) “A Method Using Fuzzy Mathematical Programming to
Solve the Vector Maximum Problem”, Fuzzy Sets and Systems, 9, ss.
129-136.FUNG, R.Y.K., J. TANG ve D. WANG; (2003), “Multiproduct Aggregate
Production Planning with Fuzzy Demands and Fuzzy Capacities”,
IEEE Transactions on Systems, Man, and Cybernetics—Part A:
Systems and Humans, 33(3), ss. 302–313.
GNON , M.G., R. IAVAGN L O, G. MOSSA, G. MUMMOLO ve A.D.
LEVA; (2003), “Production Planning of a Multi-Site Manufacturing
System by Hybrid Modelling: A Case Study from the Automotive
Industry”, International Journal of Production Economics, 85(2),
ss. 251–262.
HOLT, C., F. MODIGLIANI ve H. A. SIMON; (1955), “A Linear Decision
Rule for Production Employment Scheduling”, Management Science,
2, ss. 1-30.
JONES, C.H.; (1967) “Parametric Production Planning”, Management
Science, 13, ss. 843–866.
HUNG, Y. F. ve Y. C. HU; (1998), “Solving Mixed Integershadow Price
Information”, Computers and Operations Research, 25, ss. 1027–1042.
HUNG, Y. F., C. C. SHIH, ve C. P. CHEN; (1999), “Evolutionary Algorithms
for Production Planning Problems with Setup Decisions”, Journal of
the Operational Research Society, 50, ss. 857–866.
JOLAYEM , J.K. ve F.O. OLORUNN WO; (2004), “A Deterministic Model
for Planning Production Quantities in a Multi-Plant, Multi-Warehouse
Environment with Extensible Capacities”, International Journal of
Production Economics, 87(2), ss. 99–113.
KALL, P. ve S. W. WALLACE; (1994), Stochastic Programming Wiley -
John &Sons, 320s.
LEE, Y.Y.; (1990), Fuzzy Set Theory Approach to Aggregate Production
Planning and Inventory Control, Ph.D. Dissertation, Department of
I.E., Kansas State University.
MASUD, S.M. ve C.L. HWANG; (1980), “An Aggregate Production Planning
Model and Application of Three Multiple Objective Decision Methods”,
International Journal of Production Research, 18, ss. 741–752.
MEZGHANI, M., REBAI, A., DAMMAK ve A., LOUKIL, T.; (2008), “A Goal
Programming Model for Aggregate Production Planning Pproblem”,
International Journal of Operational Research, 4(1), ss. 23-34
MOHAMED, R.H.; (1997), The Relationship Between Goal Programming and
Fuzzy Programming, Fuzzy Sets and Systems, 89, ss. 215–222.
NAM, S. J. ve R. LOGENDRAN; (1992), “Aggregate Production Planning–A
Survey of Models and Methodologies” European Journal of
Operational Research, 61, ss. 255–272.NARAS MHAN, R.; (1980), “Goal Programming in Fuzzy Environment”,
Decision Science, 11, ss. 326-335.
NARAS MHAN, R. ve P.A. RUB N; (1984) “Fuzzy Goal Programming with
Nested Priorities”, Fuzzy Sets and Systems, 14, ss. 115–129.
OZDAMAR, L., M. A., BOZYEL ve S. I. BIRBIL; (1998), “A Hierarchical
Decision Support System for Production Planning (With Case Study)”,
European Journal of Operational Research, 104, ss. 403–422.
RAMIK, J.; (2000), “Fuzzy Goals and Fuzzy Alternatives in Goal Programming
Problems”, Fuzzy Sets and Systems, 111, ss. 81–86.
SAAD, G.; (1982), “An Overview Of Production Planning Model: Structure
Classification and Empirical Assessment”, International Journal of
Production Research, 20, ss. 105–114.
SH , Y. ve C. HAASE; (1996), “Optimal Trade-Offs of Aggregate Production
Planning with Multi-Objective and Multi-Capacity-Demand Levels”,
International Journal of Operations and Quantitative
Management, 2(2), ss. 127–143.
STEPHEN, C.H.L., Y. WU ve K.K. LA ; (2003), “Multi-Site Aggregate
Production Planning with Multiple Objectives: A Goal Programming
Approach”, Production Planning and Control, 14(5), ss. 425–436.
STEPHEN, C. H., LEUNG ve YUE WU; (2004), “A Robust Optimization Model
for Stochastic Aggregate Production Planning”, Production
Planning and Control, 15(5), ss. 502–514.
TANG, J., R.Y.K. FUNG ve K.L. YONG; (2003), “Fuzzy Modelling and
Simulation for Aggregate Production Planning”, International
Journal of Systems Science, 34(12), ss. 661–673.
TANG, J., D. WANG ve R.Y.K. FUNG;(2000) “Fuzzy Formulation for Multi-
Product Aggregate Production Planning”, Production Planning and
Control, 11, ss. 670–676.
TAUBERT, W.H.; (1968), “A Search Decision Rule for the Aggregate
Scheduling Problem”, Management Science, 14, ss. 343–359.
T WAR R.N, S. DHARMAR ve J.R. RAO; (1986), “Priority Structure in
Fuzzy Goal Programming”, Fuzzy Sets and Systems,19, ss. 251–259.
TIWARI, R. N., S. DHARMAR ve J.R. RAO; (1987), “Fuzzy Goal Programming:
An Additive Model”, Fuzzy Sets and Systems, 24, ss. 27-34.
WANG, R. C. ve H. H. FANG; (2000), “Aggregate Production Planning in A
Fuzzy Environment. International Journal of Industrial
Engineering–Theory, Applications, and Practice, 7, ss. 5–14.WANG H.F. ve C.C. FU; (1997) “A Generalization of Fuzzy Goal
Programming with Preemptive Structure, Computers & Operations
Research, 24, ss. 819–828.
WANG, D. ve S. C. FANG; (1997), “A Genetics-Based Approach for
Aggregated Production Planning in a Fuzzy Environment”, IEEE
Transactions on Systems, Man, and Cybernetics–Part A: Systems
and Human, 27, ss. 636–645.
WANG, R.C. ve T.F. LIANG; (2001), “Aggregate Production Planning with
Multiple Objectives in a Fuzzy Environment”, European Journal of
Operational Research, 133, ss. 521–536.
WANG, R.C. ve T.F. LIANG; (2004), “Application of Fuzzy Multi-Objective
Linear Programming to Aggregate Production Planning”, Computers
and Industrial Engineering, 46(1), ss. 17–41.
YAGER, R.R.; (1979), “Mathematical Programming with Fuzzy Constraints
and Preference on the Objectives”, Kybernetes, 8, ss. 285-291.
YAGHOOBl, M. A., D. F. JONES ve TAMIZ, M.; (2008), “Weighted Additive
Models for Solving Fuzzy Goal Programming Problems” Asia-Pacific
Journal of Operational Research, 25, ss. 715-733.
Y NG-YUNG, F.; (1983), “A Method Using Fuzzy Mathematics to Solve
Vector Maximum Problem”, Fuzzy Sets and Systems, 9, ss. 142-149.
ZADEH, L. A.; (1965), “Fuzzy Sets”, Information and Control, 8, ss. 338-
353.
ZIMMERMANN, H. J.; (1978), “Fuzzy Programming and Linear Programming
with Several Objective Functions”, Fuzzy Sets and System, 1, ss. 45–
55.
Z MMERMANN, H.J.; (1981), “Fuzzy Mathematical Programming”,
Computers and Operations Research, 4, ss. 291-298.

Thank you for copying data from http://www.arastirmax.com