Grooming Traffic to Maximize Throughput in SONET Rings

Using a graph-theoretic formulation, a grooming in a SONET ring network may be interpreted as a decomposition of an undirected simple graph G=(V,E), where V corresponds to the n nodes in the ring, and each edge {i, j}ϵE represents the traffic requirements for the primitive ring {i, j}. In G = {G 1 ,...

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Published in	Journal of optical communications and networking Vol. 3; no. 1; pp. 10 - 16
Main Authors	Colbourn, C J, Quattrocchi, G, Syrotiuk, V R
Format	Journal Article
Language	English
Published	IEEE 01.01.2011
Subjects	Aggregates Artificial neural networks Graph decompositions Optimized production technology SONET SONET ring Throughput Throughput maximization Traffic grooming Transceivers Upper bound
Online Access	Get full text
ISSN	1943-0620 1943-0639
DOI	10.1364/JOCN.3.000010

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Abstract	Using a graph-theoretic formulation, a grooming in a SONET ring network may be interpreted as a decomposition of an undirected simple graph G=(V,E), where V corresponds to the n nodes in the ring, and each edge {i, j}ϵE represents the traffic requirements for the primitive ring {i, j}. In G = {G 1 ,...,G 8 }, the decomposition of G, each subgraph G i specifies a set of primitive rings assigned to the same wavelength. If the maximum size set is c then G is a c-grooming. In this paper, bounding the maximum through put tp̅ (c, n, ℓ) of a c-grooming G is addressed, subject to each node being equipped with a limited number ℓ of add-drop multiplexers (ADMs). Naturally, restricting the number of ADMs limits the achievable throughput. For all ℓ, precise determinations of maximum throughput for grooming ratios c=2, 3, and 4 are given. These underlie substantially improved bounds for larger grooming ratios.
AbstractList	Using a graph-theoretic formulation, a grooming in a SONET ring network may be interpreted as a decomposition of an undirected simple graph G=(V,E), where V corresponds to the n nodes in the ring, and each edge {i, j}ϵE represents the traffic requirements for the primitive ring {i, j}. In G = {G 1 ,...,G 8 }, the decomposition of G, each subgraph G i specifies a set of primitive rings assigned to the same wavelength. If the maximum size set is c then G is a c-grooming. In this paper, bounding the maximum through put tp̅ (c, n, ℓ) of a c-grooming G is addressed, subject to each node being equipped with a limited number ℓ of add-drop multiplexers (ADMs). Naturally, restricting the number of ADMs limits the achievable throughput. For all ℓ, precise determinations of maximum throughput for grooming ratios c=2, 3, and 4 are given. These underlie substantially improved bounds for larger grooming ratios.
Author	Quattrocchi, G Syrotiuk, V R Colbourn, C J
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SubjectTerms	Aggregates Artificial neural networks Graph decompositions Optimized production technology SONET SONET ring Throughput Throughput maximization Traffic grooming Transceivers Upper bound
Title	Grooming Traffic to Maximize Throughput in SONET Rings
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