Resource Allocation in Electrical/Optical Hybrid Switching Data Center Networks

Zhangxiao Feng; Weiqiang Sun; Jie Zhu; Junyi Shao; Weisheng Hu

doi:10.1364/JOCN.9.000648

Journal of Optical Communications and Networking
Vol. 9,
Issue 8,
pp. 648-657
(2017)
•https://doi.org/10.1364/JOCN.9.000648

Resource Allocation in Electrical/Optical Hybrid Switching Data Center Networks

Zhangxiao Feng, Weiqiang Sun, Jie Zhu, Junyi Shao, and Weisheng Hu

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Zhangxiao Feng, Weiqiang Sun, Jie Zhu, Junyi Shao, and Weisheng Hu, "Resource Allocation in Electrical/Optical Hybrid Switching Data Center Networks," J. Opt. Commun. Netw. 9, 648-657 (2017)

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Abstract

Hybrid switching combines the strengths of electronic packet switching and high-speed optical circuit switching and is thus widely believed to be a cost-effective solution for current and future data center networks (DCNs). In designing a hybrid switching DCN, it is essential to know how many resources should be devoted to optical circuit switching and electronic packet switching so the performance requirements in both planes can be satisfied, and, at the same time, objectives such as minimizing the overall system building cost or the power consumption can be realized. In this paper, we introduce BLOC, the Blocking LOss Curve, as a tool to characterize hybrid switching DCNs. With BLOC, the three interacting components in hybrid switching systems—resource allocation, traffic partitioning, and system performance—can be naturally integrated and studied together. We show how BLOC can be used to obtain feasible resource allocation/traffic partition combinations. We also show how system parameters, such as flow arrival characteristics, may affect resource allocation and system costs. Our study reveals that the total amount of resource required to satisfy 95th percentile traffic can be as low as 60% of that required for 99.9th percentile traffic.

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Symbol	Definition
$C$	Total cost of network components
$V$	Total volume of flows
$C_{p}$ , $C_{c}$	Cost of PS/CS network components
$V_{p}$ , $V_{c}$	Traffic carried by PS/CS network
$T_{p}$	Flow completion time in PS network
$B_{c}$	Request blocking probability in CS network
$T_{\max}$	Flow completion time requirement
$B_{\max}$	Request blocking probability requirement

Formula	Definition
Controllable Variables:
$s$ , $p$	Number of ToR uplink interfaces connected to EPS/OCS network
$q$	Number of pairs after aggregation
$V_{p}$ , $V_{c}$	Number of bytes transmitted through EPS/OCS network
Constraints:
$C_{p} (s) + C_{c} (p, q) \leq C$	Budget constraint
$V_{p} + V_{c} = V$	Traffic transmission constraint
$T_{p} (s, V_{p}) \leq T_{\max}$	EPS network performance constraint
$B_{c} (p, q, V_{c}) \leq B_{\max}$	OCS network performance constraint
Goal:
${s, V_{p}}$	Feasible combinations of resource allocation and traffic partitioning

Component	Cost ($)	Power (W)	Number of Components
Component	Cost ($)	Power (W)	Number of EPS Ports	Number of OCS Ports
ToR port (10G)	500	12.5	$s$	$p$
EPS port	$P_{p}$	$E_{p}$	$s$	–
OCS port	$P_{c}$	$E_{c}$	–	$2 p$
Transceiver	200	1	$2 s$	$p$
Total cost ($)			$(900 + P_{p}) \times s$	$(700 + 2 P_{c}) \times p$
Total power (W)			$(14.5 + E_{p}) \times s$	$(13.5 + 2 E_{c}) \times p$

Symbol	Definition
$C$	Total cost of network components
$V$	Total volume of flows
$C_{p}$ , $C_{c}$	Cost of PS/CS network components
$V_{p}$ , $V_{c}$	Traffic carried by PS/CS network
$T_{p}$	Flow completion time in PS network
$B_{c}$	Request blocking probability in CS network
$T_{\max}$	Flow completion time requirement
$B_{\max}$	Request blocking probability requirement

Formula	Definition
Controllable Variables:
$s$ , $p$	Number of ToR uplink interfaces connected to EPS/OCS network
$q$	Number of pairs after aggregation
$V_{p}$ , $V_{c}$	Number of bytes transmitted through EPS/OCS network
Constraints:
$C_{p} (s) + C_{c} (p, q) \leq C$	Budget constraint
$V_{p} + V_{c} = V$	Traffic transmission constraint
$T_{p} (s, V_{p}) \leq T_{\max}$	EPS network performance constraint
$B_{c} (p, q, V_{c}) \leq B_{\max}$	OCS network performance constraint
Goal:
${s, V_{p}}$	Feasible combinations of resource allocation and traffic partitioning

Abstract

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Equations (11)

Journal of Optical Communications and Networking