Mapping sub-wavelength service with heterogenous security demand over physical-layer secured optical transport networks

Tianhe Liu; Wei Wang; Xiangkun Man; Huifang Xiong; Yongli Zhao; Guangquan Wang; Yajie Li; Yanxia Tan; Shan Dong; Jie Zhang

doi:10.1364/JOCN.480207

Journal of Optical Communications and Networking
Vol. 15,
Issue 5,
pp. 268-281
(2023)
•https://doi.org/10.1364/JOCN.480207

Mapping sub-wavelength service with heterogenous security demand over physical-layer secured optical transport networks

Tianhe Liu, Wei Wang, Xiangkun Man, Huifang Xiong, Yongli Zhao, Guangquan Wang, Yajie Li, Yanxia Tan, Shan Dong, and Jie Zhang

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Tianhe Liu, Wei Wang, Xiangkun Man, Huifang Xiong, Yongli Zhao, Guangquan Wang, Yajie Li, Yanxia Tan, Shan Dong, and Jie Zhang, "Mapping sub-wavelength service with heterogenous security demand over physical-layer secured optical transport networks," J. Opt. Commun. Netw. 15, 268-281 (2023)

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Abstract

In optical transport networks, client signals are usually aggregated to the lightpath channels for long-haul transport, and the aggregation process is referred to as service mapping. In the context of physical-layer secured optical networks, in which the lightpaths are encrypted, network operators need to consider not only the bandwidth demand but also the security demand of client services in the service mapping process. This paper mainly explores the service mapping issue, which decides the solution for aggregating service into the physical-layer secured optical transport network. First, we introduce the physical-layer secured optical transport networks and illustrate their differences from the traditional optical network. Then, we formulate the service mapping problem as an integer linear programming (ILP) model to maximize the number of successfully mapped services. To address the scalability issue of the ILP model, we further propose two security-aware service mapping algorithms based on the security constraints. Simulation results show that the ILP model can reach a 98.8% successful service mapping rate in a six-node mesh network. The successful service mapping rate of the heuristics is about 0.5% lower than the ILP model, which proves that the performance of the heuristics is very close to the ILP.

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	Notation	Definition
Network	$V$	The set of network nodes.
	$V_{N}$	The $N$ th node.
	$E$	The set of lightpaths.
	$E_{ij, l}$	The $l$ th lightpath from node $i$ to node $j$ .
	$B_{ij, l}$	The maximum bandwidth of $E_{ij, l}$ .
	$B_{ij, l}^{'}$	The available bandwidth of $E_{ij, l}$ .
	$Γ_{ij, l}$	The KUR of $E_{ij, l}$ .
	$τ_{ij, l}$	The security level of $E_{ij, l}$ .
	$α_{1}, \dots, α_{n}$	The customized security thresholds.
Service	$C (s, d, b, τ)$	The service originating from node $s$ to node $d$ requests a mapping path with security level $τ$ and $b$ bandwidth.
	$K$	The number of traffic matrices.
	$λ^{sd, k}$	The bandwidth requirement of the $k$ th traffic matrix from node $s$ to node $d$ .
	$τ^{sd, k}$	The security level requested by the $k$ th traffic matrix from node $s$ to node $d$ .

Parameter	Value
Topology	6-node/NSFNET topology
Maximum available bandwidth	100 Gb/s
Number of parallel lightpaths	[1,4]
Number of security level	3
Requested bandwidth	$(98.6 %) \leq 10 G b / s$
Requested security level	[1,3]
Traffic load	[0.7, 2.9] or [1.1, 27.3] Tb/s
Number of repetitions	50

	Notation	Definition
Network	$V$	The set of network nodes.
	$V_{N}$	The $N$ th node.
	$E$	The set of lightpaths.
	$E_{ij, l}$	The $l$ th lightpath from node $i$ to node $j$ .
	$B_{ij, l}$	The maximum bandwidth of $E_{ij, l}$ .
	$B_{ij, l}^{'}$	The available bandwidth of $E_{ij, l}$ .
	$Γ_{ij, l}$	The KUR of $E_{ij, l}$ .
	$τ_{ij, l}$	The security level of $E_{ij, l}$ .
	$α_{1}, \dots, α_{n}$	The customized security thresholds.
Service	$C (s, d, b, τ)$	The service originating from node $s$ to node $d$ requests a mapping path with security level $τ$ and $b$ bandwidth.
	$K$	The number of traffic matrices.
	$λ^{sd, k}$	The bandwidth requirement of the $k$ th traffic matrix from node $s$ to node $d$ .
	$τ^{sd, k}$	The security level requested by the $k$ th traffic matrix from node $s$ to node $d$ .

Parameter	Value
Topology	6-node/NSFNET topology
Maximum available bandwidth	100 Gb/s
Number of parallel lightpaths	[1,4]
Number of security level	3
Requested bandwidth	$(98.6 %) \leq 10 G b / s$
Requested security level	[1,3]
Traffic load	[0.7, 2.9] or [1.1, 27.3] Tb/s
Number of repetitions	50

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Equations (21)

Journal of Optical Communications and Networking