Dimensioning networks of ROADM cluster nodes

Hamid Mehrvar; Shiqiang Li; Eric Bernier

doi:10.1364/JOCN.481202

Journal of Optical Communications and Networking
Vol. 15,
Issue 8,
pp. C166-C178
(2023)
•https://doi.org/10.1364/JOCN.481202

Dimensioning networks of ROADM cluster nodes

Hamid Mehrvar, Shiqiang Li, and Eric Bernier

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Hamid Mehrvar, Shiqiang Li, and Eric Bernier, "Dimensioning networks of ROADM cluster nodes," J. Opt. Commun. Netw. 15, C166-C178 (2023)

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About this Article
History
- Original Manuscript: November 22, 2022
- Revised Manuscript: January 30, 2023
- Manuscript Accepted: March 16, 2023
- Published: June 21, 2023
Virtual Issues
Journal of Optical Communications and Networking ECOC 2022 (2023)

Abstract

Next-generation optical networks require high-degree, high-capacity reconfigurable optical add-drop multiplexer (ROADM) nodes and intelligent network planning schemes. We propose a cluster ROADM node design and a network dimensioning method that optimizes the resource utilization of optical networks with cluster nodes. The proposed ROADM cluster node offers a flexible add-drop rate, scaling to 100s of degrees, and a cost per degree similar to today’s ROADM. It disaggregates the cluster’s line and add-drop functions into different chassis. The low-cost node architecture is complemented by an order-based connection management algorithm that achieves better than ${10^{- 4}}$ blocking despite being equipped with less than 30% dilation in the cluster design. For an optical network with ROADM cluster nodes, we propose a network dimensioning scheme that proactively uses network knowledge to determine the optimum degree for ROADM nodes as demand increases. The results show a much-improved blocking rate, particularly at medium to high loading and an average of 3.1% increased utilization on each network’s fiber compared with reactive schemes.

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$M \geq 2 N - 1$ $N = 11$ , $M = 21$	Case 1: $g = 8$ ; $h = 8$	Case 2: $g = 10$ ; $h = 6$	Case 3: $g = 12$ ; $h = 4$	Case 4: $g = 14$ ; $h = 2$	Case 5: $g = 16$ ; $h = 0$
Degree ( $d$ )	88	110	132	154	176
Add-drop rate	100%	60%	33%	14%	0%
Cost per degree	$0.24 a$	$0.19 a$	$0.16 a$	$0.14 a$	$0.12 a$

$M < 1.3 N$ $N = 14$ , $M = 18$	Case 1: $g = 8$ ; $h = 8$	Case 2: $g = 10$ ; $h = 6$	Case 3: $g = 12$ ; $h = 4$	Case 4: $g = 14$ ; $h = 2$	Case 5: $g = 16$ ; $h = 0$
Degree ( $d$ )	112	140	168	196	224
Add-drop rate	100%	60%	33%	14%	0%
Cost per degree	$0.18 a$	$0.15 a$	$0.12 a$	$0.11 a$	$0.09 a$

	Case 1	Case 2	Case 3	Case 4	Case 5
# of line chassis ( $g$ )	8	10	12	14	16
# of add-drop chassis ( $h$ )	8	6	4	2	0
Number of degrees	112	140	168	196	224
Add-drop rate	100%	60%	33%	14%	0%
Total traffic channels	17,920	17,920	17,920	17,920	17,920
Total channels added	8960	6720	4480	2240	0
Total channels dropped	8960	6720	4480	2240	0
Pass-through channels	0	4480	8960	13,440	17,920
Mean blocking (load balancing)	0.0104	0.0103	0.0102	0.0104	0.0116
Mean blocking (random routing)	0.0079	0.079	0.08	0.0084	0.009
Mean blocking (order based)	$3.5 \times 1 0^{- 6}$	$4.7 \times 1 0^{- 6}$	$7.2 \times 1 0^{- 6}$	$1.3 \times 1 0^{- 5}$	$1.8 \times 1 0^{- 5}$

Algorithm’s Connectivity Time	Min	Max	Mean
Order based	0.32 µs	3.2 µs	0.43 µs
Random routing	1.24 µs	17.6 µs	1.75 µs
Load balancing	2.1 µs	30 µs	2.76 µs

Urban Area	Node Number
Beijing	5
Xian	10
Nanjing	12
Shanghai	13
Wuhan	17
Chengdu	19
Guangzhou	22

Abstract

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Journal of Optical Communications and Networking