Load-Dependent Power-Efficient Passive Optical Network Architectures

Ganesh C. Sankaran; Krishna M. Sivalingam

doi:10.1364/JOCN.6.001104

Journal of Optical Communications and Networking
Vol. 6,
Issue 12,
pp. 1104-1114
(2014)
•https://doi.org/10.1364/JOCN.6.001104

Load-Dependent Power-Efficient Passive Optical Network Architectures

Ganesh C. Sankaran and Krishna M. Sivalingam

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Ganesh C. Sankaran and Krishna M. Sivalingam, "Load-Dependent Power-Efficient Passive Optical Network Architectures," J. Opt. Commun. Netw. 6, 1104-1114 (2014)

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Abstract

Passive optical networks consume nearly 70% of peak power even when the network load is almost zero (i.e., off-peak). To reduce power consumption under low-load conditions, we propose the concept of a flexible network architecture. Each architecture is a unique combination of central office, subscriber, and end-user equipment variants. Three such architectures are proposed. The architecture that minimizes the overall power consumption of the network can be chosen provided its network performance is within an acceptable range. Using numerical evaluation, we observe that three of these architectures perform better than the others. We describe the network operation for these architectures and then evaluate their network performance using simulations. For two of the studied scenarios, it is shown that at least 35% power savings can be achieved by adopting a proposed architecture during off-peak network loads, without significant performance impact in terms of throughput and packet delay.

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Equipment	$C_{1}$	$C_{0}$	$S_{1}$	$S_{2}$	$S_{0}$	$E_{2}$	$E_{1}$
$P (Eqpt)$	1.05	30.0	1	2	4	—	0
$P (Trx)$	—	1.25	—	—	1	1.5	—

Parameter	Value
ONU-OLT distance	Uniform distribution (15, 20) km
EN-ONU distance	Uniform distribution (100, 150) m
Message processing time	1 μs
Packet length	Uniform distribution (64, 1500) bytes
Network load	From 250 Mbps to 2.5 Gbps per OLT port
Report message size	64 bytes
Grant message size	64 bytes
EN-ONU line rate	1 Gbps
ONU-OLT line rate	2.5 Gbps
ONU packet buffer size	2 MB
EN packet buffer size	256 kB

Rule	Expansion	Changes to $P$ and $B$	Values for $γ$
$R_{1}$	$S \to D S D$	$P \underset{=}{+} P (E_{0}) + P (C_{0})$	$I$ , $C$
$R_{2}$	$S \to X P Y$	$B \underset{=}{-} B (R N) + B (O F)$	$I$ , $C$
$R_{3}$	$X \to AD X$	$P \underset{=}{+} P (E_{2}) + P (C_{2})$	$I$ , $C$
$R_{4}$	$X \to DD X$	$P \underset{=}{+} P (E_{0}) + P (S_{0})$	$I$ , $C$
$R_{5}$	$X \to A$	$P \underset{=}{+} P (S_{1})$	$V$ , $I$ , $C$
$R_{6}$	$X \to D$	$P \underset{=}{+} P (S_{0})$	$V$ , $I$ , $C$
$R_{7}$	$Y \to P Y$	$B \underset{=}{-} B (C_{2})$	$V$ , $I$ , $C$
$R_{8}$	$Y \to A Y$	$B > O^{'} ? I : C$	$V$ , $I$ , $C$
$R_{9}$	$Y \to λ$	—	—

Equipment	$C_{1}$	$C_{0}$	$S_{1}$	$S_{2}$	$S_{0}$	$E_{2}$	$E_{1}$
$P (Eqpt)$	1.05	30.0	1	2	4	—	0
$P (Trx)$	—	1.25	—	—	1	1.5	—

Parameter	Value
ONU-OLT distance	Uniform distribution (15, 20) km
EN-ONU distance	Uniform distribution (100, 150) m
Message processing time	1 μs
Packet length	Uniform distribution (64, 1500) bytes
Network load	From 250 Mbps to 2.5 Gbps per OLT port
Report message size	64 bytes
Grant message size	64 bytes
EN-ONU line rate	1 Gbps
ONU-OLT line rate	2.5 Gbps
ONU packet buffer size	2 MB
EN packet buffer size	256 kB

Load-Dependent Power-Efficient Passive Optical Network Architectures

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Equations (4)

Journal of Optical Communications and Networking