Abstract
Das kapazitierte Standortproblem, welches in der englischsprachigen Literatur als „Capacitated Facility Location Problem“ (CFLP) bezeichnet wird, ist eine sehr bekannte kombinatorische Optimierungsaufgabe mit zahlreichen Anwendungen in der Produktions- und Distributionsplanung. Das Problem besteht in der Auswahl von Standorten für Depots bzw. Warenlager aus einer gegebenen Menge potentieller Standorte und der Bestimmung der Liefermengen an gegebene Kundenorte derart, dass die Nachfragemengen zu minimalen totalen Kosten — bestehend aus den Kosten des Transports sowie den variablen und fixen Standortkosten — bei Beachtung gegebener Kapazitätsgrenzen für die Umschlagsmengen der Depotstandorte befriedigt werden können. Zur exakten und approximativen Lösung dieser Aufgabe wurden in der Literatur eine Reihe von Verfahren vorgestellt. Exakte Branch-and-Bound-Algorithmen beruhen dabei i. d. R. auf Lagrange- Relaxationen und dem Einsatz von Subgradientenverfahren. Dies hat den Nachteil, dass zum Aufbau des Enumertionsbaumes keine (fraktionalen) primalen Lösungen als Leitlinie zur Verfügung stehen. Mit Hilfe von Verfahren der Spaltengenerierung lässt sich jedoch die zur Lagrange-Schranke gehörige primale Lösung ermitteln. In dieser Arbeit wird ein auf diesem Prinzip beruhendes Branch-and-Bound-Verfahren vorgestellt, wobei vor allem die Untersuchung unterschiedlicher Regeln zur Bestimmung der Verzweigungsvariablen im Vordergrund steht.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Preview
Unable to display preview. Download preview PDF.
Literatur
Aardal K (1998) Capacitated facility location: Separation algorithm and computational experience. Math Programming 81: 149–175
Aardal K, Pochet Y, Wolsey LA (1995) Capacitated facility location: Valid inequalities and facets. Math Oper Res 20: 552–582
Achterberg T, Koch T, Martin A (2005) Branching rules revisited. Oper Res Letters 33: 42–54
Barnhart C, Johnson EL, Nemhauser GL, Savelsbergh MWP, Vance PH (1998) Branch-and-price: Column generation for solving huge integer programs. Oper Res 46: 316–329
Beasley JE (1988) An algorithm for solving large capacitated warehouse location problems. European J Oper Res 33: 314–325
Boffey TB (1989) Location problems arising in computer networks. J Oper Res Soc 40: 347–354
Christofides N, Beasley JE (1983) Extensions to a Lagrangean relaxation approach for the capacitated warehouse location problem. European J Oper Res 12: 19–28
Cornuéjols G, Sridharan R, Thizy J-M (1991) A comparison of heuristics and relaxations for the capacitated plant location problem. European J Oper Res 50:280–297
Dantzig GB, Wolfe P (1960) Decomposition principle for linear programs. Oper Res 8: 101–111
Delmaire H, Díaz JA, Fernández E (1999) Reactive GRASP and tabu search based heuristics for the single source capacitated plant location problem. INFOR — Canad J Oper Res Inform Process 37: 194–225
Domschke W, Drexl A (1985) ADD-heuristics’ starting procedures for capacitated plant location models. European J Oper Res 21:47–53
Forrest JJH, Hirst JPH, Tomlin JA (1974) Practical solution of large mixed integer programming problems with UMPIRE. Management Sci 20: 736–773
Geoffrion AM, McBride R (1978) Lagrangean relaxation applied to capacitated facility location problems. AIIE Trans 10: 40–47
Goffin J-L, Vial J-P (2002) Convex nondifferentiable optimization: A survey focussed on the analytic center cutting plane method. Optimization Methods and Software 17: 805–867
Harkness J, ReVelle C (2003) Facility location with increasing production costs. European J Oper Res 145: 1–13
Jacobsen SK (1983) Heuristics for the capacitated plant location model. European J Oper Res 12:253–261
Khumawala BM (1974) An efficient heuristic procedure for the capacitated warehouse location problem. Naval Res Logist Quart 21: 609–623
Klose A, Drexl A (2001) Lower bounds for the capacitated facility location problem based on column generation. Arbeitsbericht, Universität St. Gallen, http://www.wiwi.uni-wuppertal.de/fileadmin/OR/00-09-03.pdf. Letzter Abruf: 30.09.2004
Klose A, Görtz S (2003) A branch-and-price algorithm for the capacitated facility location problem. Arbeitsbericht, Bergische Universität Wuppertal, http://www.wiwi.uni-wuppertal.de/fileadmin/OR/03-12-30.pdf. Letzter Abruf: 30.09.2004
Klose A, Görtz, S (2004) An exact column generation algorithm for the capacitated facility location problem. In: Fleischmann B, Klose A (eds) Distribution Logistics: Advanced Solutions to Practical Problems. Lecture Notes in Economics and Mathematical Systems, vol 544, Springer, Berlin, pp 1–26
Kochmann GA, McCallum CJ (1981) Facility location models for planning a transatlantic communications network. European J Oper Res 6: 205–211
Korupolu MR, Plaxton CG, Rajaraman R (2000) Analysis of a local search heuristic for facility location problems. J Algorithms 37: 146–188.
Kuehn AA, Hamburger MJ (1963) A heuristic program for locating warehouses. Management Sci 9: 643–666
Lemaréchal C (1989) Nondifferentiable optimization. In: Nemhauser GL, Rinnooy Kan AHG, Todd MJ (eds.) Optimization. Handbooks in Operations Research and Management Science, vol 1, North-Holland, Amsterdam, pp 529–572
Leung JMY, Magnanti TL (1989) Valid inequalities and facets of the capacitated plant location problem. Math Programming 44: 271–291
Linderoth JT, Savelsbergh MWP (1999) A computational study of search strategies for mixed integer programming. Informs J Comp 11: 173–187
Magnanti TL, Wong RT (1981) Accelerating Benders decomposition: Algorithmic enhancement and model selection criteria. Oper Res 29: 464–484
Martello S, Pisinger D, Toth P (1999) Dynamic programming and strong bounds for the 0–1 knapsack problem. Management Sci 45: 414–424
Mateus GR, Bornstein CT (1991) Dominance criteria for the capacitated warehouse location problem. J Oper Res Soc 42: 145–149
Mirzaian A (1985) Lagrangian relaxation for the star-star concentrator location problem: Approximation algorithm and bounds. Networks 15: 1–20
Nauss RM (1978) An improved algorithm for the capacitated facility location problem. J Oper Res Soc 29: 1195–1201
Pochet Y, Wolsey LA (1988) Lot-size models with backlogging: Strong reformulations and cutting planes. Math Programming 40: 317–335
Rolland E, Schilling DA, Current JR (1996) An efficient tabu search procedure for the p-median problem. European J Oper Res 96: 329–342
Van Roy TJ (1986) A cross decomposition algorithm for capacitated facility location. Oper Res 34: 145–163
Ryu C, Guignard M (1992) An efficient algorithm for the capacitated plant location problem. Working Paper 92-11-02, Decision Sciences Department, University of Pennsylvania, The Wharton School
Shetty B (1990) Approximate solutions to large scale capacitated facility location problems. Appl Math and Comput 39: 159–175
Shmoys DB, Tardos É, Aardal K (1997) Approximation algorithms for facility location problems. In: Proceedings of the 29th Annual ACM Symposium on Theory of Computing, pp 265–274
Wentges P (1996) Accelerating Benders’ decomposition for the capacitated facility location problem. Math Methods Oper Res 44: 267–290
Wentges P (1997) Weighted Dantzig-Wolfe decomposition for linear mixedinteger programming. Internat Trans Oper Res 4: 151–162
Author information
Authors and Affiliations
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2005 Physica-Verlag Heidelberg
About this paper
Cite this paper
Görtz, S., Klose, A. (2005). Das kapazitierte Standortproblem: Branch-and-Price und die Wahl der Verzweigungsvariable. In: Günther, HO., Mattfeld, D.C., Suhl, L. (eds) Supply Chain Management und Logistik. Physica-Verlag HD. https://doi.org/10.1007/3-7908-1625-6_23
Download citation
DOI: https://doi.org/10.1007/3-7908-1625-6_23
Publisher Name: Physica-Verlag HD
Print ISBN: 978-3-7908-1576-4
Online ISBN: 978-3-7908-1625-9
eBook Packages: Business and Economics (German Language)