Journal of Optical Communications and Networking
Vol. 1,
Issue 3,
pp. B81-B97
(2009)
•https://doi.org/10.1364/JOCN.1.000B81

Design and Analysis of Optical Flow-Switched Networks

Guy Weichenberg, Vincent W.S. Chan, and Muriel Médard

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Guy Weichenberg, Vincent W.S. Chan, and Muriel Médard, "Design and Analysis of Optical Flow-Switched Networks," J. Opt. Commun. Netw. 1, B81-B97 (2009)

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Related Topics
Table of Contents Category
- Architectures and Technologies for Ultra-High Capacity Switched and Routed Optical Networks
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About this Article
History
- Original Manuscript: November 30, 2008
- Revised Manuscript: April 1, 2009
- Manuscript Accepted: June 6, 2009
- Published: July 31, 2009

Abstract

In our previous work [Chan et al., “Optical flow switching,” in BROADNETS 2006, pp. 1–8; Weichenberg et al., “Cost-efficient optical network architectures,” in ECOC 2006, pp. 1–2; Weichenberg et al., “On the throughput-cost tradeoff of multi-tiered optical network architectures,” GLOBECOM '06, pp. 1–6], we presented optical flow switching (OFS) as a key enabler of scalable future optical networks. We now address the design and analysis of OFS networks in a more comprehensive fashion. The contributions of this work, in particular, are in providing partial answers to the questions of how OFS networks can be implemented, how well they perform, and how their economics compare with those of other architectures. With respect to implementation, we present a sensible scheduling algorithm for inter-metropolitan-area-network (inter-MAN) OFS communication. Our performance study builds upon our work in IEEE J. Sel. Areas Commun. , vol. 25, no. 6, pp. 84–101, 2007 and Weichenberg et al., “Performance analysis of optical flow switching,” presented at the IEEE International Conference on Communications, Dresden, Germany, June 14–18, 2009, and includes a comparative capacity analysis for the wide area, as well as an analytical approximation of the throughput-delay trade-off offered by OFS for inter-MAN communication. Last, with regard to the economics of OFS, we extend our previous work from ECOC 2006 and GLOBECOM '06 in carrying out an optimized throughput-cost comparison of OFS with other prominent candidate architectures. Our conclusions indicate that OFS offers a significant advantage over other architectures in economic scalability. In particular, for sufficiently heavy traffic, OFS handles large transactions at far lower cost than other optical network architectures. In light of the increasing importance of large transactions to communication networks, we conclude that OFS may be crucial to the future viability of optical networking.

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Parameter	Value
No. of nodes	60
No. of links	77
Average node degree	2.6
Largest node degree	5
Average link length	$450 km$
Longest link length	$1200 km$
Optical amplifier spacing	$80 km$
Number of wavelength channels per fiber link	200
Average length of an end-to-end connection	$1950 km$
Average no. of hops of an end-to-end connection	4
Average no. of nonnodal regenerations along an end-to-end connection in EPS	0.1
Average no. of regenerations along an end-to-end connection in OCS or OFS	0.3
Capacity efficiency scaling factor	0.95
Line rate	$40 Gbits / s$

Parameter	Value
No. of nodes	30
Average link length	$10 km$
OFS hardware reconfiguration time	$10 ms$
Line rate	$40 Gbits / s$

Parameter	Value
Average end-user link length	$35 m$
End-user duty cycle	0.001
Ratio of PON line rate to WAN line rate	0.25
OFS DN line rate	$40 Gbits / s$
PON line rate	$10 Gbits / s$

Network Element	Relative Cost
Network Element	$10 Gbits / s$	$40 Gbits / s$
Tunable medium-reach transceiver	$0.3 x$	$0.75 x$
Tunable long-reach WDM transceiver	$0.4 x$	x
Tunable WDM transponder	$40 x$	$100 x$
Tunable WDM regenerator (with optical line terminal)	$56 x$	$140 x$
Optical terminal chassis (per wavelength)	$2.5 x$	$2.5 x$
WAN amplifier and dispersion compensation (per wavelength)	$2 x$	$3.1 x$
WAN OXC port with amplification and dispersion compensation	$8 x$	$9.1 x$
WAN router port	$120 x$	$300 x$
MAN OXC port with amplification	$5 x$	$5.1 x$
MAN grooming/router port	$60 x$	$150 x$
OFS scheduler	$2 x$	$2 x$
Access fiber deployment (per km wavelength)	$0.2 x$	$0.2 x$
MAN fiber deployment (per km wavelength)	$0.2 x$	$0.2 x$
WAN fiber deployment (per km wavelength)	$0.1 x$	$0.1 x$
Access network erbium-doped fiber amplifier pump power (per $100 mW$ )	$2 x$	$2 x$

Parameter	Value
Cost ratio of 10 to $40 Gbit / s$ amplifier and dispersion compensation equipment	0.64
Cost ratio of 10 to $40 Gbit / s$ electronics	0.4
Cost ratio of 600 to $2500 km$ optical reach equipment	0.63

Design and Analysis of Optical Flow-Switched Networks

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Journal of Optical Communications and Networking