Computing minimum 2-edge-connected Steiner networks in the Euclidean plane

Marcus Brazil; Marcus Volz; Martin Zachariasen; Charl Ras; Doreen A. Thomas

Computing minimum 2-edge-connected Steiner networks in the Euclidean plane

Marcus Brazil, Marcus Volz, Martin Zachariasen, Charl Ras, Doreen A. Thomas

Research output: Journal Article or Conference Article in Journal › Journal article › Research › peer-review

Abstract

We present a new exact algorithm for computing minimum 2-edge-connected Steiner networks in the Euclidean plane. The algorithm is based on the GeoSteiner framework for computing minimum Steiner trees in the plane. Several new geometric and topological properties of minimum 2-edge-connected Steiner networks are developed and incorporated into the new algorithm. Comprehensive experimental results are presented to document the performance of the algorithm which can reliably compute exact solutions to randomly generated instances with up to 50 terminals—doubling the range of existing exact algorithms. Finally, we discuss the appearance of Hamiltonian cycles as solutions to the minimum 2-edge-connected Steiner network problem.

Original language	English
Journal	Networks
Pages (from-to)	89-103
ISSN	0028-3045
Publication status	Published - 2019
Externally published	Yes

Keywords

Minimum 2-edge-connected Steiner networks
Euclidean plane
GeoSteiner framework
Geometric properties
Hamiltonian cycles

Cite this

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title = "Computing minimum 2-edge-connected Steiner networks in the Euclidean plane",

abstract = "We present a new exact algorithm for computing minimum 2-edge-connected Steiner networks in the Euclidean plane. The algorithm is based on the GeoSteiner framework for computing minimum Steiner trees in the plane. Several new geometric and topological properties of minimum 2-edge-connected Steiner networks are developed and incorporated into the new algorithm. Comprehensive experimental results are presented to document the performance of the algorithm which can reliably compute exact solutions to randomly generated instances with up to 50 terminals—doubling the range of existing exact algorithms. Finally, we discuss the appearance of Hamiltonian cycles as solutions to the minimum 2-edge-connected Steiner network problem.",

keywords = "Minimum 2-edge-connected Steiner networks, Euclidean plane, GeoSteiner framework, Geometric properties, Hamiltonian cycles, Minimum 2-edge-connected Steiner networks, Euclidean plane, GeoSteiner framework, Geometric properties, Hamiltonian cycles",

author = "Marcus Brazil and Marcus Volz and Martin Zachariasen and Charl Ras and Thomas, {Doreen A.}",

year = "2019",

language = "English",

pages = "89--103",

journal = "Networks",

issn = "0028-3045",

publisher = "Wiley-Blackwell",

}

TY - JOUR

T1 - Computing minimum 2-edge-connected Steiner networks in the Euclidean plane

AU - Brazil, Marcus

AU - Volz, Marcus

AU - Zachariasen, Martin

AU - Ras, Charl

AU - Thomas, Doreen A.

PY - 2019

Y1 - 2019

N2 - We present a new exact algorithm for computing minimum 2-edge-connected Steiner networks in the Euclidean plane. The algorithm is based on the GeoSteiner framework for computing minimum Steiner trees in the plane. Several new geometric and topological properties of minimum 2-edge-connected Steiner networks are developed and incorporated into the new algorithm. Comprehensive experimental results are presented to document the performance of the algorithm which can reliably compute exact solutions to randomly generated instances with up to 50 terminals—doubling the range of existing exact algorithms. Finally, we discuss the appearance of Hamiltonian cycles as solutions to the minimum 2-edge-connected Steiner network problem.

AB - We present a new exact algorithm for computing minimum 2-edge-connected Steiner networks in the Euclidean plane. The algorithm is based on the GeoSteiner framework for computing minimum Steiner trees in the plane. Several new geometric and topological properties of minimum 2-edge-connected Steiner networks are developed and incorporated into the new algorithm. Comprehensive experimental results are presented to document the performance of the algorithm which can reliably compute exact solutions to randomly generated instances with up to 50 terminals—doubling the range of existing exact algorithms. Finally, we discuss the appearance of Hamiltonian cycles as solutions to the minimum 2-edge-connected Steiner network problem.

KW - Minimum 2-edge-connected Steiner networks

KW - Euclidean plane

KW - GeoSteiner framework

KW - Geometric properties

KW - Hamiltonian cycles

KW - Minimum 2-edge-connected Steiner networks

KW - Euclidean plane

KW - GeoSteiner framework

KW - Geometric properties

KW - Hamiltonian cycles

M3 - Journal article

SN - 0028-3045

SP - 89

EP - 103

JO - Networks

JF - Networks

ER -

Computing minimum 2-edge-connected Steiner networks in the Euclidean plane

Abstract

Keywords

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