Optical switching will innovate intra data center networks [Invited Tutorial]

Ken-ichi Sato

doi:10.1364/JOCN.495006

Journal of Optical Communications and Networking
Vol. 16,
Issue 1,
pp. A1-A23
(2024)
•https://doi.org/10.1364/JOCN.495006

Optical switching will innovate intra data center networks [Invited Tutorial]

Ken-ichi Sato

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Ken-ichi Sato, "Optical switching will innovate intra data center networks [Invited Tutorial]," J. Opt. Commun. Netw. 16, A1-A23 (2024)

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About this Article
History
- Original Manuscript: May 11, 2023
- Revised Manuscript: July 17, 2023
- Manuscript Accepted: July 18, 2023
- Published: December 4, 2023
Virtual Issues
Journal of Optical Communications and Networking OFC 2023 (2024)

Abstract

Reflecting the recent slow-down in Moore’s law and the proliferation of artificial intelligence/machine learning workloads, the performance and energy consumption of networks are becoming barriers in high-performance computing (HPC) and data centers. Optical switches are expected to break these barriers, and indeed their introduction has recently commenced in data centers. This paper discusses how optical switching technologies can innovate future intra data center networks. Hyperscale data centers are much bigger in scale, and network requirements are slightly different from those of HPC. This paper focus on data center networks, since the impact of optical technologies will be more significant in data centers than in HPC. In addition to the scale issue, important metrics to be considered for network design are traffic characteristics and latency, both of which are highlighted in this paper. For hybrid (electrical packet and optical circuit) switching networks, the target latency for the optical circuit switch network (connection setup/teardown time) is shown to be around 10 µs, and the needed technologies are clarified and verified by experiments. The optical switch can simplify the present multi-tier switching network above tier-1 switches into a single tier configuration, which is possible with the development of efficient large port count optical switches. Among the different switching architectures, combining the different dimensions of space and wavelength is shown to be one of the best solutions. Fast switching needs fast device response time. Si photonics devices using Mach–Zehnder interferometers or ring-resonator-based switches and tunable filters are the most promising candidates; they offer cost-effective mass-production and fast operation and so are excellent candidates for the optical switches envisaged. Another critical technology to maximize the benefits of optical switches is a simple and low-latency control mechanism. Different approaches have been suggested as summarized in this work. Among them, harnessing optical switch parallelism is a unique technique that matches recent advances in electrical switch chips. A fast control network is realized by using a fully decentralized and asynchronous control mechanism. A hyperscale data center offers a wide variety of services, and no one system fits all needs. Optimization of parameters is an important task for maximizing the impact of optical switching in different kinds of data centers.

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Name (Country)	Achievement	# of Racks
Frontier (USA)	#1, 2022 June	74
Fugaku (富岳) (Japan)	#1, 2021 Nov	432
Summit (USA)	#1, 2018 June	256
TaifuLight (神威·太湖之光) (China)	#2, 2016 June	40
Tianhe-2 (天河二号) (China)	#3, 2013 June	125
ABCI (Japan)	#5, 2018 June	32
Piz Daint (Europe)	#3, 2017 June	36
Oakforest-PACS (Japan)	#6, 2016	102
Kei (京)(Japan)	#1, 2011 June	864

	HPC	Data Center
System (organization)	Oakforest-PACS (Tokyo Univ./Tsukuba Univ.: Top 500 6-rank, 2016)	Jupiter (Google 5th generation)
Operation period	Dec. $2016 \sim$	$2012 \sim$
No. of nodes/servers	8688	$\sim 400$ thousand
Network topology	Two-tier fat tree (InfiniBand)	Three-tier fat tree (Ethernet)
Switch chip bandwidth	4.8 Tbps (Omni-Path)	0.64 Tbps (Ethernet)
No. of tier-1 switches	362	8192
Total # of switch chip tiers	3	5
Total # of switch chips	1,130	$> 20,000$

	Data Center	AI/Machine Learning	High-Performance Computing
System evolution	Incremental update: plural vendors and generation systems coexist, non-uniform link speed. Network is based on Ethernet/IP.	Replace the system every generation: network is created with single vendor switches, uniform link speed. Various interconnect technologies are used.
Traffic pattern	Web: E-W traffic dominates. Variety of patterns for implementing wide range of services.	Graph analysis: Random access to large memory sets. DNN training: AllReduce ring, model parallel mesh.	Scientific analysis: nearest neighbor predominate.
No. of cabinets/racks	$> 10, 000$	$< 100$ (indirect) (# of nodes $> 10^{3}$ )	$< \sim 400$ (indirect) (# of nodes $> 10^{5}$ )
Interconnect (network) requirement	Flexible bandwidth provisioning, large bisection bandwidth	Fast I/O, short reach, large bandwidth (training), low latency (inference)	Low latency, remote direct memory access, large bandwidth
Interconnect network topology	(Three-tier) fat tree	Direct: n-D Torus, ring (AllReduce), tree (parameter server), peer-to-peer. Indirect: fat tree, BCube	Direct: n-D Torus, 6D mesh/torus. Indirect (two-tier): tree, fat tree, Dragonfly
Effectiveness of electrical/optical hybrid switching (relative)	+ +	+ +^a	+^a

	(a) Baseline	(c) Approach 2	(d) Approach 3
	Electrical Switch Network	Replacing Spine Layer with Small Optical Switches	Replacing Spine and Leaf Layers with Large Optical Switches
No. of electrical switches (leaf + spine)	3072	2048	384
No. of optical switches (switch scale)	—	512^b ( $128 \times 128$ )	28 ( $2, 048 \times 2, 048$ )
No. of transceivers (400 Gbps, inc. ToRs)	262,144	196,608	77,824

		Fig. 8(c) Approach 2	Fig. 8(d) Approach 3^b
Optical switch		Small port count, large number (ex. $128 \times 128$ , 512)	Large port count, small number (ex. $2048 \times 2048$ , 28–56)
Average # of optical switch traversals between ToR switches		$> 1$ (depends on OCS size etc., ex. 1.4^a)	1 (between ToR switches)
No. of electrical switch chip traversals between ToR switches		2–3 (4–7^a)	0 (direct optical connection)
Network control	Traffic engineering (control frequency)	Centralized (second-minutes), split traffic among multiple shortest and non-shortest paths	None (using connection setup/teardown control) (common incast congestion control is needed)
Network control	Topology engineering (control frequency)	Centralized (hour)	Distributed ( $\sim 10 µ s$ : on demand connection setup, select one from multiple free direct paths)
Switch network incremental growth		Ease leaf/aggregation switch upgrade (not applicable to ToR switches)	Ease ToR switch upgrade

Operation Principle	Platform	Port Count	Switching Time	Insertion Loss [dB]	Cross Talk [dB]	Refs.
Microelectrical mechanical systems	3D MEMS	320	50 ms	3	−60	[76]
Microelectrical mechanical systems	3D MEMS	136	$\sim 1 m s$	2	−38	[74]
Piezoelectric	Free-space optics	576	75–100 ms	3.0	−50	[77]
Electro-static	Silicon photonics (2D MEMS)	64	0.91 µs	3.7	−60	[78]
Electro-static	Silicon photonics (2D MEMS)	240	0.78 µs	9.8	−70	[79]
Thermo-optic	Silicon photonics	8	24 µs	11.1	–	[80]
		8	15 µs	15	−35	[81]
		16	21.78 µs	5.2	−30	[82]
		32	30 µs	28.4	−20	[83]
		32	5 µs	12.8	−20	[84]
	Silica planar light wave circuit	8	84 µs	(multicast switch)	–	[85]
Elcctro-optic	Silicon photonics	8	10 ns	10.5	−20	[86]
		16	1.65 ns	10.6	−20.5	[87]
		16	20 ns	19	−33	[88]
		32	1.2 ns	20.8	−14.1	[89]
		8	8 ns	10	−25	[90]
Wavelength routing	Silica cyclic arrayed wavelength grating	90 (combination of $9 \times 9$ and $10 \times 10$ AWGs)	–	13.3	−40	[44]
Wavelength routing	Silicon nitride cyclic arrayed wavelength grating	8	few ns	6	$- 15$	[91]

	System	Network Configuration (above ToR)	Control Scheme	Connection between	Opt. Connection Setup Time (Hardware Switching Time)	# of Optical Switches	Control Plane Algorithm (Global Scheduling)	Refs.
	C-Through	EPS/OCS hybrid	Centralized	End host (server)	A few ms	1	Edmonds	[68]
	Helios	EPS/OCS hybrid	Centralized	(ToR/)POD switch	$> 10 m s$	1-plural	Edmonds	[69]
	OSA	OCS	Centralized	ToR	300 ms	1	Edmonds	[62]
	Mordia	EPS/Optical time slot switching (OCS)	Centralized	ToR	(Av. 11 µs switch hardware time)	Many WSSs	BvN	[70]
	REACToR	EPS/OCS hybrid	Centralized	Server	O (100 µs)	1	Solstice	[71]
	Firefly	OCS	Centralized	ToR	68 ms	1 (free- space optics)	Blossom	[63]
	High-radix, low-latency optical switch	Optical time slot switching	Centralized/distributed	Server or ToR	(2 µs epoch; NW sync, needed)	1 (star coupler)	WL & time slot alignment	[64]
	Large port count parallel optical switches	EPS/OCS hybrid	Schedule-less	ToR	7–20 µs (200 m floor)	# of ToR upper links	Unnecessary (FC-FS based)	[72]
	Large port count parallel optical switches	EPS/OCS hybrid	Schedule-less	ToR	7–20 µs (200 m floor)	# of ToR upper links	Unnecessary (FC-FS based)	[35]
	PULSE	Optical time slot switching	Distributed	Server (node)	(Scheduling tail latency: 1–100 µs at 50% load)	(# of ToR)² couplers		[73]
	ProjecToR	Optical time slot switching	Distributed	ToR	80 µs (examine proposals), (12 µs sw time)	Multiple (12)	Extended Gale Shapely (offline)	[65]
	RotorNet	Optical time slot switching	Distributed	ToR/POD switch	3.2 ms (2048 racks)	Many rotor sw (ex. $12 \times 12$ )	VLB variant	[66]
	Sirius	Optical cell switching	Static schedule (uniformly detoured)	Server or ToR	Two-way fixed delay + ( $> 1.6 µ s$ ) network epoch	1	Uniformly detoured two-hop connection (static schedule with time synchronization)	[67]
Partial replacement (hybrid in terms of switching tiers)	Jupiter (Google)	OCSs replaces spine switches	Centralized	Aggregation switches	O (hour)	Several hundred ( $136 \times 136$ )	Flow measurements from every server to form the block-level traffic matrix	[30]

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Journal of Optical Communications and Networking