Bounding the expected number of rectilinear full Steiner trees

Christian Wulff-Nilsen

doi:10.1002/net.20342

Bounding the expected number of rectilinear full Steiner trees

Department of Computer Science

Abstract

Given a finite set Z of n points, called terminals, in Rd , the Rectilinear Steiner Tree Problem asks for a tree of minimal L₁-length spanning Z . An optimal solution has a unique decomposition into full Steiner trees (FSTs). By using geometric properties and combinatorial arguments, we bound the expected number of FSTs satisfying simple necessary conditions for being part of an optimal solution. More specifically, we show that the expected number of FSTs spanning exactly K terminals and satisfying the empty lune property, a weak version of the bottleneck property, and the so-called empty hyperbox property is O(n(log log n)^2(d-1)) for K = 3 and O(n(log log n)^d-1 log^K-2 n) for K > 3, assuming terminals are randomly distributed in a hypercube with aniform distribution. In the plane, we improve an earlier bound by showing that the expected number of FSTs with the Hwang form spanning exactly K terminals and satisfying the empty lune property and the so-called disjoint lunes property is O(nπK ).

Original language	English
Journal	Networks
Volume	56
Issue number	1
Pages (from-to)	1-10
Number of pages	10
ISSN	0028-3045
DOIs	https://doi.org/10.1002/net.20342
Publication status	Published - Aug 2010

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title = "Bounding the expected number of rectilinear full Steiner trees",

abstract = "Given a finite set Z of n points, called terminals, in Rd , the Rectilinear Steiner Tree Problem asks for a tree of minimal L1-length spanning Z . An optimal solution has a unique decomposition into full Steiner trees (FSTs). By using geometric properties and combinatorial arguments, we bound the expected number of FSTs satisfying simple necessary conditions for being part of an optimal solution. More specifically, we show that the expected number of FSTs spanning exactly K terminals and satisfying the empty lune property, a weak version of the bottleneck property, and the so-called empty hyperbox property is O(n(log log n)2(d-1)) for K = 3 and O(n(log log n)d-1 logK-2 n) for K > 3, assuming terminals are randomly distributed in a hypercube with aniform distribution. In the plane, we improve an earlier bound by showing that the expected number of FSTs with the Hwang form spanning exactly K terminals and satisfying the empty lune property and the so-called disjoint lunes property is O(nπK ).",

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AU - Wulff-Nilsen, Christian

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N2 - Given a finite set Z of n points, called terminals, in Rd , the Rectilinear Steiner Tree Problem asks for a tree of minimal L1-length spanning Z . An optimal solution has a unique decomposition into full Steiner trees (FSTs). By using geometric properties and combinatorial arguments, we bound the expected number of FSTs satisfying simple necessary conditions for being part of an optimal solution. More specifically, we show that the expected number of FSTs spanning exactly K terminals and satisfying the empty lune property, a weak version of the bottleneck property, and the so-called empty hyperbox property is O(n(log log n)2(d-1)) for K = 3 and O(n(log log n)d-1 logK-2 n) for K > 3, assuming terminals are randomly distributed in a hypercube with aniform distribution. In the plane, we improve an earlier bound by showing that the expected number of FSTs with the Hwang form spanning exactly K terminals and satisfying the empty lune property and the so-called disjoint lunes property is O(nπK ).

AB - Given a finite set Z of n points, called terminals, in Rd , the Rectilinear Steiner Tree Problem asks for a tree of minimal L1-length spanning Z . An optimal solution has a unique decomposition into full Steiner trees (FSTs). By using geometric properties and combinatorial arguments, we bound the expected number of FSTs satisfying simple necessary conditions for being part of an optimal solution. More specifically, we show that the expected number of FSTs spanning exactly K terminals and satisfying the empty lune property, a weak version of the bottleneck property, and the so-called empty hyperbox property is O(n(log log n)2(d-1)) for K = 3 and O(n(log log n)d-1 logK-2 n) for K > 3, assuming terminals are randomly distributed in a hypercube with aniform distribution. In the plane, we improve an earlier bound by showing that the expected number of FSTs with the Hwang form spanning exactly K terminals and satisfying the empty lune property and the so-called disjoint lunes property is O(nπK ).

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DO - 10.1002/net.20342

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Bounding the expected number of rectilinear full Steiner trees

Abstract

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