Load-Aware Nonlinearity Estimation for Elastic Optical Network Resource Optimization and Management

Rui Wang; Sarvesh Bidkar; Fanchao Meng; Reza Nejabati; Dimitra Simeonidou

doi:10.1364/JOCN.11.000164

Journal of Optical Communications and Networking
Vol. 11,
Issue 5,
pp. 164-178
(2019)
•https://doi.org/10.1364/JOCN.11.000164

Load-Aware Nonlinearity Estimation for Elastic Optical Network Resource Optimization and Management

Rui Wang, Sarvesh Bidkar, Fanchao Meng, Reza Nejabati, and Dimitra Simeonidou

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Rui Wang, Sarvesh Bidkar, Fanchao Meng, Reza Nejabati, and Dimitra Simeonidou, "Load-Aware Nonlinearity Estimation for Elastic Optical Network Resource Optimization and Management," J. Opt. Commun. Netw. 11, 164-178 (2019)

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Abstract

Elastic optical networks (EONs) have emerged as a promising technology to accommodate the high-capacity and dynamic bandwidth demands of next-generation wireless networks. However, similar to the traditional wavelength division multiplexing optical networks, there exist significant challenges to manage nonlinearity effects in EONs. In this paper, we first analyze state-of-the-art nonlinearity estimation solutions and propose a novel load-aware nonlinearity estimation method. We further present a resource allocation algorithm using the proposed nonlinearity estimation scheme. In case the new embedded lightpath brings additional nonlinearity blocking the existing requests, we propose a mixed integer linear programming model and two heuristic algorithms using the proposed nonlinearity model as the service reconfiguration scheme for efficient resource allocation in EONs. The objective of the solution is to minimize the spectrum resource usage while satisfying the bandwidth demands of the connection and ensuring the quality of transmission. The proposed solutions are evaluated using an extensive simulation with off-line traffic requests and incrementally loaded requests against the benchmark solutions for two types of traffic profiles in a small network with six nodes and nine links and the National Science Foundation network. The results presented in this paper validate the benefits of the proposed nonlinearity estimation model and the corresponding algorithms to minimize the number of allocated frequency slots and service request blocking ratio while improving the overall network capacity.

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$l s$	1	2	3	4	5
PSD (mW/THz)	28.99	24.97	23.77	23.05	22.55
$l s$	6	7	8	9	10
PSD (mW/THz)	22.18	21.88	21.63	21.42	21.24

Symbol	Meaning
$N$	Number of the requests
$L$	Number of the links
$F$	Number of the frequency slots
$M$	Number of the modulation formats
LS	Number of the loading states
$K$	Number of the shortest path

Symbol	Meaning
$G_{ASE} \in R > 0$	Per span power spectrum density of ASE noise
$G_{sig} \in R > 0$	Signal PSD launched into the fiber
$b \in R > 0$	Bandwidth of each frequency slot
$μ \in N > 0$	A very large number ( $\sim 10^{4}$ )
$P_{n, k, l} \in B = {0, 1}$	Pre-calculated $K$ paths, $P_{n, k, l} = 1$ if $k$ th path of connection $n$ uses link $l$
${SP}_{l} \in N$	Number of fiber spans of link $l$
${SNR}_{m} \in R > 0$	SNR threshold for modulation scheme $m$
$T_{n} \in R > 0$	Bit-rate request of connection $n$
$B_{n, m}^{FS} \in N$	Number of frequency slots required for connection $n$ when assigned modulation scheme is $m$
$G_{NLI}^{l s, f} \in R > 0$	Per span NLI PSD of frequency slot $f$ for a link of loading state $l s$ (NLI lookup table)

Symbol	Meaning
$x_{k, m, f}^{n} \in B$	$x_{k, m, f}^{n} = 1$ if frequency slot $f$ , modulation format $m$ , and $k$ th path is assigned to connection $n$ , 0 otherwise
$z_{k, m}^{n} \in B$	$z_{k, m}^{n} = 1$ if modulation format $m$ and $k$ th path is assigned to connection $n$ , 0 otherwise
${Mod}_{n, m} \in B$	${Mod}_{n, m} = 1$ if connection $n$ utilizes modulation format $m$ , 0 otherwise
$y_{l s, l} \in B$	$y_{l s, l} = 1$ if link $l$ is within $l s$ loading state, 0 otherwise
$P R_{l, f}^{n} \in B$	$P R_{l, f}^{n} = 1$ if connection $n$ uses link $l$ and frequency slot $f$ , 0 otherwise
$d_{l, f} \in B$	$d_{l, f} = 1$ if frequency slot $f$ is the maximum frequency slot index allocated in link $l$ , 0 otherwise
$H_{l, f} \in N$	$H_{l, f} = f$ if $f$ is occupied for link $l$ , 0 otherwise
${FS}_{\min}^{n} \in N$	Minimum assigned frequency slot index of connection $n$
${FS}_{\max}^{n} \in N$	Maximum assigned frequency slot index of connection $n$
${MF}_{l} \in N$	Maximum frequency slot index of link $l$
$E_{NLI}^{n, l} \in R \geq 0$	Nonlinearity PSD per span in link $l$ of connection $n$
$MF_\max \in N$	Maximum frequency slot index of all of the links

Signal PSD (mW/THz)	DP-BPSK	DP-QPSK	DP-8QAM	DP-16QAM
10.64	9680	4800	1920	1040
13.40	11600	5760	2240	1200
16.87	13120	6560	2560	1360
21.24	13760	6880	2720	1440
26.73	13040	6480	2560	1360
33.66	10960	5440	2160	1120
42.38	8240	4080	1600	880

	PSD 10.6	PSD 13.4	PSD 16.9	PSD 21.2	PSD 26.7	PSD 33.7	PSD 42.4
PH1	198	194	186	180	176	183	192
PH2	206	202	196	189	180	185	198
PM	216	196	198	190	171	194	203
BI	290	286	282	281	289	290	317
BH	288	277	270	262	270	280	335

Signal PSD (mW/THz)	9.7	12.2	15.3	19.3	24.3	30.6	38.5
Low-to-medium traffic	0.07	1.3	17	21	33	53	45
Medium-to-large traffic	0.02	1	12	14	21	34	26

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Journal of Optical Communications and Networking