Difference between revisions of "Facility location problems"
|Line 54:||Line 54:|
Define decision variables i=1,2,3,4 such that [[File:x21.png
Define decision variables i=1,2,3,4 such that [[File:x21.png|left|upright=1.1]]. Then the total expected benefit is: [[File:x22.png|left|upright=1.1]] <br> and the total capital needed is: [[File:x23.png|left|upright=1.1]]
In total, the model can be given as: [[File:x24.png
In total, the model can be given as: [[File:x24.png|left|upright=1.1]]
Revision as of 22:03, 24 May 2015
Author: Aaron Litoff
Stewards: Dajun Yue and Fengqi You
The facility location problems deal with selecting the placement of a facility (often from a list of integer possibilities) to best meet the demanded constraints. The problem consists of selection a factory location that minimizes total weighted distances from suppliers and customers, where weights are representative of the difficulty of transporting materials. The solution to this problem gives the highest profit choice that most efficiently serves the needs of all customers.
The Fermat-Weber problem was one of the first facility location problems every proposed, and was done so as early as the 17th century. This "geometric median of three points" can be thought of as a version of the facility location problem where the assumption is made that transportation costs per distance are the same for all destinations. It was put forth by the French mathematician Pierre de Fermat to the Italian physicist Evangelista Torricelli as follows:
"Given three points in a plane, find a fourth point such that the sum of its distances to the three given points is as small as possible." 
In 1909 Alfred Weber used a three point version to model possible industrial locations in order to minimize transportation costs from two sources of materials to a single customer market.  This formulation is one the simplest continuous facility location models.
The Fermat-Weber Problem given mathematically:
Given a finite number of distinct points File:Example.jpg and positive multipliers File:Example.jpg find a point File:Example.jpg
that minimizes File:Example.jpg
. The simplest version of this problem with all w=1 and n=2 gives the minimum distance in a flat plane.
A modern day engineering interpretation of Fermat's formulation could be as follows:
"Find the best location for a refining plant between three cities in such a way that the sum of the connections between the plant and the cities in minimal."
Although this problem was first solved geometrically by Torricelli in 1645 it did not have a direct numerical solution until Kuhn and Kuenne's iterative method was published over 300 years later in 1962! 
Description and Formulation
In the uncapacitated facility location problem, the number of possible locations is now finite as we have discrete choices of where to build. These choices are governed by binary decision variables y.
The problem is defined as a set of customers D, a set of facilites f, a fixed cost for opening each facility, and a variable cost for each facility. We are looking for the subset S of facilites that we should open and an assignment of D to s customers that will be serviced by each facility such taht the sum of facility costs and variable costs are minimized.~
These problems have been studied extensively in the literature and are often solved using an approximation algorithm. The approximation algorithm looks for a feasible solution where
Examples and Applications
A Real World Example
Suppose you are a manager at Apple and you are identifying locations to sell computers and iPhones in a new location in Chicago. You would start by identifying potential sites in a variety of neighborhoods throughout the city and finding the demand for Apple products in each neighborhood. Then to construct your model you could create a table of neighborhoods, the cost of building a new Apple store in each one and the expected profit. Your goal now is to select which facilities should be built in order to maximize profit.
and the total capital needed is:
Note that in another formulation of this problem you could minimize distance for customers to travel to the store regardless of profit.
Applications in Industry
applications in diverse �elds including public policy (e.g., locating �re stations in a city), telecommunications (e.g., locating base stations in wireless networks), and information retrieval (e.g., clustering of documents)
Applications in physics, solution to Fermat-Weber problem allowing for "repulsion" or negative distances.
Many economical decision problems concern selecting and/or placing certain facilities to serve given demands efficiently. Examples are manufacturing plants, storage facilities, depots, warehouses, libraries, fire stations, hospitals, base stations for wireless services (like TV broadcasting or mobile phone service), etc. The problems have in common that a set of facilities, each with a certain position, has to be chosen, and the objective is to meet the demand (of customers, users etc.) best. Facility location problems, which occur also in less obvious contexts, indeed have numerous applications.
 Dorrie, H. (1965) 100 great problems of elementary mathematics: their history and solution. New York, NY: Dover Publications.
 Drezner, Z & Hamacher. H. W. (2004). Facility location: applications and theory. New York, NY: Springer.
 Weisstein, E. W. Fermat Points. Mathworld-- A wolfram web resource. http://mathworld.wolfram.com/FermatPoints.html
 Kuhn, H. W. and Kuenne, R. E. (1962). An efficient algorithm for the numerical solution of the generalized weber problem in spatial economics. Journal of Regional Science, 4.
Author, A. A., & Author, B. B. (Date of publication). Title of article. Title of Online Periodical, volume number(issue number if available). Retrieved from http://www.someaddress.com/full/url/
Last, F. M. (Year Published) Book. City, State: Publisher.