Multi-tenant provisioning over software defined networking enabled metropolitan area quantum key distribution networks

Yuan Cao; Yongli Zhao; Xiaosong Yu; Jie Zhang

doi:10.1364/JOSAB.36.000B31

Journal of the Optical Society of America B
Vol. 36,
Issue 3,
pp. B31-B40
(2019)
•https://doi.org/10.1364/JOSAB.36.000B31

Multi-tenant provisioning over software defined networking enabled metropolitan area quantum key distribution networks

Yuan Cao, Yongli Zhao, Xiaosong Yu, and Jie Zhang

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Yuan Cao, Yongli Zhao, Xiaosong Yu, and Jie Zhang, "Multi-tenant provisioning over software defined networking enabled metropolitan area quantum key distribution networks," J. Opt. Soc. Am. B 36, B31-B40 (2019)

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Abstract

Quantum key distribution (QKD) has potential to provide long-term security for communications across the Internet. As security-hungry applications dramatically rise nowadays, a growing number of QKD networks are promising to be deployed in the immediate future. Nevertheless, a high-security-demand institution (e.g., a bank) needs to pay a high price to deploy its dedicated QKD network, while a cost-effective way of overcoming this challenge is to make multiple tenants share a QKD network. Each tenant represents a high-security-demand institution and can obtain secret keys on demand from the QKD network infrastructure for security purposes. Hence, how to achieve efficient and flexible multi-tenant provisioning over a QKD network becomes a crucial problem. This work introduces software defined networking (SDN) to address this problem. We experimentally demonstrate multi-tenant provisioning (including tenant establishment, adjustment, and deletion) over SDN-enabled metropolitan area QKD networks. A SDN-enabled metropolitan area QKD network architecture is introduced. We present a workflow, protocol extensions, and an on-demand secret-key resource allocation strategy for multi-tenant provisioning, which are all demonstrated by establishing an experimental testbed in the lab. Experimental results verify the effectiveness and flexibility of our SDN-based approaches for multi-tenant provisioning over metropolitan area QKD networks. Moreover, we conduct the simulation and discover the ways of improving the success probability of multi-tenant provisioning over metropolitan area QKD networks.

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Notations	Definitions
$G (V, E)$	Metropolitan area QKD network topology
$V$	Set of QKD nodes
$E$	Set of QKD links
$T$	A period of time for producing $K$ units of secret-key resources between two QKD nodes
$K$	The produced number of secret-key resources between two QKD nodes within $T$
$R$	Set of incoming tenant requests within $T$
$r (V_{r}, K_{r}, t_{r - a}, t_{r - d}, t_{r - m})$	A tenant request
$V_{r}$	Set of QKD nodes which are connected to the data communication equipment of $r$
$K_{r}$	Set of secret-key resource requirements corresponding to the security requirement of $r$
$t_{r - a}$	Arrival time of tenant request $r$
$t_{r - d}$	Departure time of tenant request $r$
$t_{r - m}$	Triggering period of tenant adjustment
$k_{r - i j}$	The secret-key resource requirement between two QKD nodes $i$ and $j$ in $V_{r}$
$i$ , $j$	Index the QKD nodes in $V_{r}$
$Z$	The category of tenant-adjustment triggering periods
$Δ t$	The interval of adjacent tenant-adjustment triggering periods
$A_{i j}$	The real-time available number of secret-key resources between two QKD nodes $i$ and $j$
$N$	Set of accepted tenant requests at the arrival time $t_{r - a}$ of tenant request $r$
$n$	Index the tenant request in $N$
$C$	The total number of accepted tenant requests within $T$

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Journal of the Optical Society of America B