Hybrid amplifier placement in mesh DWDM networks using integer linear programming models

João Pedro; João Pedro; Nelson Costa

doi:10.1364/JOCN.493242

Journal of Optical Communications and Networking
Vol. 15,
Issue 10,
pp. E29-E39
(2023)
•https://doi.org/10.1364/JOCN.493242

Hybrid amplifier placement in mesh DWDM networks using integer linear programming models

João Pedro and Nelson Costa

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João Pedro and Nelson Costa, "Hybrid amplifier placement in mesh DWDM networks using integer linear programming models," J. Opt. Commun. Netw. 15, E29-E39 (2023)

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About this Article
History
- Original Manuscript: April 14, 2023
- Revised Manuscript: May 29, 2023
- Manuscript Accepted: June 13, 2023
- Published: September 11, 2023
Virtual Issues
Journal of Optical Communications and Networking Optical Networks and Systems (ONS) Symposium at GLOBECOM 2022 (2023)

Abstract

Hybrid erbium-doped fiber (EDF)/Raman amplifiers (HFAs) can be utilized to improve the performance of specific fiber spans in dense wavelength division multiplexing (DWDM) networks, aiming to extend the reach and/or increase the capacity of optical channels, thereby reducing the total number of line interfaces required to satisfy a given set of traffic demands. However, HFAs are costlier than simpler EDF amplifiers (EDFAs) since they include Raman pumps in addition to an EDFA. Consequently, it is paramount to place them only at selected fiber spans of the network so as to maximize their impact while keeping their number limited. It has been shown that HFA placement can be a complex task in mesh DWDM networks in view of optical channel diversity, with each fiber span traversed by multiple channels with different source and destination nodes. Building on the approximation that noise adds up incoherently along the transmission path, this paper proposes optimal methods to solve the problem of placing hybrid amplifiers in mesh networks. Particularly, it describes two integer linear programming models, one to determine the minimum number and location of HFAs required to reach a target set of feasible optical channels (i.e., without intermediate 3R regenerators) and another to maximize the number of feasible optical channels given a limited number of HFAs to be deployed. A comprehensive set of network simulations using three reference optical network topologies is reported, providing insight into the effectiveness of the proposed models when compared to existing approaches.

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	INN	PEN	JNN
#ROADMs	44	49	48
#Links	142	144	164
Av. link span count	2.82	3.92	2.10
#Fiber spans	400	564	340
Span length range	4 to 100 km	2 to 130 km	10 to 96.4 km
Av. span length	65.4 km	99.4 km	74.2 km
Fiber types	SSMF, LEAF	SSMF, LEAF	SSMF

Fiber Type	Attenuation Parameter [dB/km]	Dispersion Parameter [ps/nm/km]	Nonlinear Coefficient [1/W/km]
SSMF	0.21	16.8	1.07
LEAF	0.22	4.8	1.29

	100G	150G	200G	300G	400G
Symbol rate [Gbaud]	34	34	34	63.1	63.1
Modulation format	QPSK	8QAM	16QAM	8QAM	16QAM
FEC overhead	25%	25%	25%	15%	15%
${R O S N R}_{B 2 B}$ [dB]	11	15	18	21	24

			Number of HFAs, $\| S^{*} \|$
$K$	$A_{min} (\| S^{'} \|)$	$\| T_{max} \|$	Att-HP	Gre-HP	Opt-HP^a
1	21 dB (40)	1114	26	12	12 (0%)
	20 dB (54)	1132	54	26	24 (−8%)
	19 dB (104)	1158	104	62	58 (−6%)
	18 dB (158)	1260	158	108	104 (−4%)
4	21 dB (40)	3756	36	34	32 (−6%)
	20 dB (54)	4068	54	48	46 (−4%)
	19 dB (104)	4256	104	98	96 (−2%)
	18 dB (158)	4740	158	152	150 (−1%)

Channel			Number of HFAs, $\| S^{*} \|$
Format	$A_{min} (\| S^{'} \|)$	$\| T_{max} \|$	Att-HP	Gre-HP	Opt-HP^a
100G	25 dB (44)	1374	44	34	34 (0%)
(QPSK)	24 dB (112)	1592	112	108	108 (0%)
	23 dB (196)	1694	196	160	158 (−1%)
	22 dB (336)	1786	306	246	236 (−4%)
	21 dB (458)	1872	450	356	302 (−15%)
	20 dB (492)	1874	484	376	324 (−14%)
150G	25 dB (44)	550	44	32	32 (0%)
(8QAM)	24 dB (112)	664	110	90	88 (−2%)
	23 dB (196)	728	194	156	150 (−4%)
	22 dB (336)	750	306	234	214 (−9%)
	21 dB (458)	816	450	340	290 (−15%)
	20 dB (492)	820	476	352	298 (−15%)
200G	25 dB (44)	226	44	26	26 (0%)
(16QAM)	24 dB (112)	248	112	68	64 (−6%)
	23 dB (196)	262	178	114	104 (−9%)
	22 dB (336)	286	270	132	118 (−11%)
	21 dB (458)	310	450	188	166 (−12%)
	20 dB (492)	316	492	210	188 (−11%)

		Number of HFAs, $\| S^{*} \|$		Number of Feasible Channels, $\| T_{max}^{*} \|$
Channel Format	$N$	Att-HP	Opt-HP	Att-HP	Opt-HP	$Δ T$
300G (8QAM)	0	0	0	1292	1292	0
	10	10	10	1292	1336	44
	20	20	20	1330	1374	44
	30	30	30	1350	1404	54
	40	40	40	1358	1412	54
	50	50	48	1368	1422	54
	58	58	58	1376	1428	52
400G (16QAM)	0	0	0	522	522	0
	10	10	10	536	548	12
	20	20	20	552	570	18
	30	30	30	560	584	24
	40	40	38	564	594	30
	50	50	48	574	600	26
	60	60	58	580	604	24

Abstract

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Tables (6)

Equations (17)

Journal of Optical Communications and Networking