Abstract / Description of output
We consider facility location problems where n facilities are present in a convex polygon in the rectilinear plane, over which continuous and uniform demand is distributed and within which a convex polygonal barrier is located (removing all demand and preventing all travel within the barrier), and the optimal location for an additional facility is sought. We start with an in-depth analysis of the representation of the bisectors of two facilities affected by the barrier and how it is affected by the position of the additional facility. Following this, a detailed investigation into the changes in the structure of the Voronoi diagram caused by the movement of this additional facility, which governs the form of
the objective function for numerous facility location problems, yields a set of linear constraints for a general convex barrier that partitions the market space into a finite number of regions within which the exact solution can be found in polynomial time. This allows us to formulate a polynomial exact
algorithm that makes use of a triangular decomposition of the incremental Voronoi diagram and the
first order optimality conditions.
the objective function for numerous facility location problems, yields a set of linear constraints for a general convex barrier that partitions the market space into a finite number of regions within which the exact solution can be found in polynomial time. This allows us to formulate a polynomial exact
algorithm that makes use of a triangular decomposition of the incremental Voronoi diagram and the
first order optimality conditions.
Original language | English |
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Number of pages | 38 |
Journal | European Journal of Operational Research |
Early online date | 16 Feb 2021 |
DOIs | |
Publication status | E-pub ahead of print - 16 Feb 2021 |