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1998 | Buch

Introduction Kapitel lesen Erstes Kapitel lesen

Discrete and Fractional Programming Techniques for Location Models

verfasst von: Ana Isabel Barros

Verlag: Springer US

Buchreihe : Combinatorial Optimization

Enthalten in: Professional Book Archive

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At first sight discrete and fractional programming techniques appear to be two com­ pletely unrelated fields in operations research. We will show how techniques in both fields can be applied separately and in a combined form to particular models in location analysis. Location analysis deals with the problem of deciding where to locate facilities, con­ sidering the clients to be served, in such a way that a certain criterion is optimized. The term "facilities" immediately suggests factories, warehouses, schools, etc. , while the term "clients" refers to depots, retail units, students, etc. Three basic classes can be identified in location analysis: continuous location, network location and dis­ crete location. The differences between these fields arise from the structure of the set of possible locations for the facilities. Hence, locating facilities in the plane or in another continuous space corresponds to a continuous location model while finding optimal facility locations on the edges or vertices of a network corresponds to a net­ work location model. Finally, if the possible set of locations is a finite set of points we have a discrete location model. Each of these fields has been actively studied, arousing intense discussion on the advantages and disadvantages of each of them. The usual requirement that every point in the plane or on the network must be a candidate location point, is one of the mostly used arguments "against" continuous and network location models.

Inhaltsverzeichnis

Frontmatter
One. Introduction
Abstract
At first sight discrete and fractional programming techniques appear to be two completely unrelated fields in operations research. We will show how techniques in both fields can be applied separately and in a combined form to particular models in location analysis.
Ana Isabel Barros
Two. Discrete Location Models
Abstract
Discrete location deals with deciding where to locate facilities within a finite set of sites, taking into account the needs of the clients to be served in such a way that a given criterion is optimized. In this description there are several vague points, like the existence or not of additional constraints on the facilities, the way clients demand is satisfied, and so forth. Hence, by particularizing these points different models arise. For instance, the existence or not of capacities on the supplies creates either capacitated or uncapacitated models, and the number of levels of facilities to be located yields either 1-level or multi-level location problems.
Ana Isabel Barros
Three. Location Models and Fractional Programming
Abstract
The discrete location models discussed in the previous chapter distinguish the location decisions by the total net profit. The total net profit measures the gains of a certain location decision, i.e. the difference between the sum of the profits associated with serving each client via certain facilities and the fixed costs associated with those facilities. This traditional criterion assumes that the profits and fixed costs are available and correctly computed. In operations research the subject of finding these parameters is usually left to economists and finance consultants. However, as we shall see, it may be decisive to understand how economists obtain the data in order to correctly apply the models studied in the previous chapter. Therefore, we will briefly introduce some of the most popular economical concepts, which are discussed in greater detail by Brealey and Myers [30].
Ana Isabel Barros
Four. Generalized Fractional Programming
Abstract
In the previous chapter we considered some location models with a ratio as objective function. This discussion showed the importance of having a good knowledge of fractional programming when solving a fractional location model. As we shall see in Section 4.1.2 there exist also models in location analysis which are actually generalized fractional programs. Therefore, we will devote this chapter to generalized fractional programming, where the goal is to minimize the largest of several ratios of functions. One of the earliest examples of generalized fractional programming problem corresponds to Von Neumann’s model of an expanding economy, see [100]. Other applications can be found in economic equilibrium problems, management applications of goal programming and multi-objective programming involving ratios of functions, and rational approximation in numerical analysis, see [42, 124]. Let x m be a nonempty set and f j , g j : C → , , jJ : = { 1, ..., n}, n ≥ 1, be a class of continuous functions where C is an open set containing χ.
Ana Isabel Barros
Five. Summary and Remarks
Abstract
The first part of this book was dedicated to the analysis of discrete location models, in particular to the 2-level extensions of the uncapacitated facility location problem. We presented a new model for an uncapacitated 2-level location problem. This new model explores the relations among the facilities to be located by considering simultaneously the fixed costs of opening facilities in the two levels and also the fixed costs of having facilities operating together. As a result, the model generalizes known models in the literature, like the uncapacitated facility location problem, the 2- echelon uncapacitated facility location problem and the 2-level uncapacitated facility location problem. For our general model we discussed three different formulations and derived lower and upper bounds which were tested in branch and bound schemes. The specialization of these results to the 2-echelon uncapacitated facility location problem and the 2-level uncapacitated facility location problem improves the known existing results for these problems. Moreover, it also suggests the importance of deriving valid inequalities for these 2-level problems. The computational experience indicates that the 2-level types of problems have distinct behaviors. In particular, it appears that the “easiest” 2-level problems is the 2-echelon uncapacitated facility location problem, while the “hardest” is the 2-level uncapacitated facility location problem.
Ana Isabel Barros
Backmatter
Metadaten
Titel
Discrete and Fractional Programming Techniques for Location Models
verfasst von
Ana Isabel Barros
Copyright-Jahr
1998
Verlag
Springer US
Electronic ISBN
978-1-4615-4072-4
Print ISBN
978-1-4613-6824-3
DOI
https://doi.org/10.1007/978-1-4615-4072-4