Steiner trees with infinitely many terminals on the sides of an angle
Abstract
The Euclidean Steiner problem is the problem of finding a set St, with the shortest length, such that St A is connected, where A is a given set in a Euclidean space. The solutions St to the Steiner problem will be called Steiner sets while the set A will be called input. Since every Steiner set is acyclic we call it Steiner tree in the case when it is connected. We say that a Steiner tree is indecomposable if it does not contain any Steiner tree for a subset of the input. We are interested in finding the Steiner set when the input consists of infinitely many points distributed on two lines. In particular we would like to find a configuration which gives an indecomposable Steiner tree. We consider a self-similar input, namely the set Aα,λ of points with coordinates (λk-1 α, λk-1 α), where λ>0 and α>0 are small fixed values. These points are distributed on the two sides of an angle of size 2α in such a way that the distances from the points to the vertex of the angle are in a geometric progression. To our surprise, we show that in this case the solutions to the Steiner problem for Aα,λ, when α and λ are small enough, are always decomposable trees. More precisely, any Steiner tree for Aα,λ is a countable union of Steiner trees, each one connecting 5 points from the input. By considering only a finite number of components we obtain many solutions to the Steiner problem for finite sets composed of 4k+1 points distributed on the two lines (2k+1 on a line and 2k on the other line). These solutions are very similar to the ladders of Chung and Graham.
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