Disaggregated optical-layer switching for optically composable disaggregated computing [Invited]

Kiyo Ishii; Ryosuke Matsumoto; Takashi Inoue; Shu Namiki

doi:10.1364/JOCN.471132

Journal of Optical Communications and Networking
Vol. 15,
Issue 1,
pp. A11-A25
(2023)
•https://doi.org/10.1364/JOCN.471132

Disaggregated optical-layer switching for optically composable disaggregated computing [Invited]

Kiyo Ishii, Ryosuke Matsumoto, Takashi Inoue, and Shu Namiki

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Kiyo Ishii, Ryosuke Matsumoto, Takashi Inoue, and Shu Namiki, "Disaggregated optical-layer switching for optically composable disaggregated computing [Invited]," J. Opt. Commun. Netw. 15, A11-A25 (2023)

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About this Article
History
- Original Manuscript: July 22, 2022
- Revised Manuscript: September 9, 2022
- Manuscript Accepted: October 5, 2022
- Published: October 31, 2022
Virtual Issues
Journal of Optical Communications and Networking OFC 2022 (2023)

Abstract

Disaggregated computing has been widely investigated to support the continuous progress in computing performance and overcome the slowdown of Moore’s law. It involves a flexible and optimal interconnection of heterogeneous compute nodes, such as the CPU, GPU, xPU, memory, and storage, to offer an efficient computing environment for various applications. Such a scheme inherently requires high network performance, including low latency, high capacity, determinism, and energy efficiency, all of which are simultaneously achieved through the introduction of optical-layer switching. This paper presents the application of optical-layer-switching architectures to disaggregated computing. Networks associated with disaggregated computing are classified into intra- and interserver networks. Focusing on the intraserver network, a holistic concept of optically composable disaggregated computing (OCDC) is discussed, along with its technological direction toward future digital infrastructure (i.e., the computing continuum). To realize OCDC, scalable and flexible optical switch technologies, as well as their dynamic and automatic control and management mechanisms, are indispensable. Previous studies have reported ${32} \times {32}$ silicon photonic switches that can form a nine-stage Clos topology with a radix of 131,072 and a machine-processable function description model for optical-layer switching, called the functional block-based disaggregation model (FBD model) that is capable of automating the operation, administration, and management of any optical physical topology in cooperation with upper-layer operating systems. This study examines their applicability to OCDC. The superior energy performance and scaling of an OCDC system equipped with optical matrix switches, such as silicon photonic switches, with respect to the conventional one big electrical packet-switching approach based on the reported wall-plug power consumption is also presented. The potential applicability of the FBD model as an essential control and management system for the optical layer of OCDC is evaluated through numerical experiments.

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Symbol	Parameter	Value
$N$	Number of disaggregated nodes per bunch	100
$k$	Number of disaggregated servers per bunch	8
$L$	Number of WDM channels	8
$α$	Ratio of connection to upper layer (%)	28
$C$	I/O bandwidth per WDM channel (Gbps)	400
$B$	Throughput per electrical switch (Tbps)	51.2
$n$	Number of ports of an elementary optical switch	32
$P_{A S I C}$	Power consumption per electrical switch (W)	1750
$P_{O S W}$	Power consumption per optical switch (W)	23.6
$P_{O A}$	Power consumption per OA (W)	3

Element Switch	Total Ports	XML File Size [kB]	# of Components	# of Fiber Connections
$4 \times 4$	$8 \times 8$	36	28	48
$8 \times 8$	$32 \times 32$	116	88	192
$16 \times 16$	$128 \times 128$	254	304	768
$32 \times 32$	$512 \times 512$	1817	1120	3072

Symbol	Description
$M$	Set of components configuring the node/network
$V$	Set of ports of all components
$L$	Set of wavelength channels that the node/network supports
$V_{m}^{M}$	Set of ports belonging to component $m \in M$
$V_{m}^{MO}$	Set of output ports belonging to component $m \in M$
$V_{m}^{MI}$	Set of input ports belonging to component $m \in M$
$C_{m}$	Set of possible connections inside component $m \in M$ consisting of four dimensions $(i, j, k, l)$ for $i \in V_{m}^{MI}, k \in V_{m}^{MO}, a n d j, l \in L .$
$C$	Set of possible connections in the node/network under consideration. Thus, in addition to the connections inside the component, $C_{m} \forall m \in M$ , the fiber cables between the components are considered; each of the elements has four dimensions $(i, j, k, l)$ for $i, k \in V$ and $j, l \in L$
$V_{v}^{S}$	Set of ports that can send signals to port $v \in V$
$V_{v}^{R}$	Set of ports that can receive signals from port $v \in V$
$D$	Set of demands
$s (d)$	Source port of the demand $d$
$e (d)$	Destination port of the current demand $d$
$b_{ijkl}^{m}$	Boolean decision variable that equals 1 if the connection $(i, j, k, l) \in C_{m}$ is activated
$x_{ijkl}^{d}$	Boolean decision variable that equals 1 if the connection $(i, j, k, l) \in C$ is assigned to the demand $d$ , otherwise 0
$x^{d}$	Boolean decision variable that equals 1 if the demand $d$ is accommodated
$y_{ijkl}$	Boolean decision variable that equals 1 if the connection $(i, j, k, l) \in C$ is not assigned to any demands ( $\in D$ ) while it is assigned during the normal phase, otherwise 0
$A_{ijkl}$	Boolean constant that equals 1 if the connection $(i, j, k, l) \in C$ is assigned during the normal phase, otherwise 0

Symbol	Parameter	Value
$N$	Number of disaggregated nodes per bunch	100
$k$	Number of disaggregated servers per bunch	8
$L$	Number of WDM channels	8
$α$	Ratio of connection to upper layer (%)	28
$C$	I/O bandwidth per WDM channel (Gbps)	400
$B$	Throughput per electrical switch (Tbps)	51.2
$n$	Number of ports of an elementary optical switch	32
$P_{A S I C}$	Power consumption per electrical switch (W)	1750
$P_{O S W}$	Power consumption per optical switch (W)	23.6
$P_{O A}$	Power consumption per OA (W)	3

Element Switch	Total Ports	XML File Size [kB]	# of Components	# of Fiber Connections
$4 \times 4$	$8 \times 8$	36	28	48
$8 \times 8$	$32 \times 32$	116	88	192
$16 \times 16$	$128 \times 128$	254	304	768
$32 \times 32$	$512 \times 512$	1817	1120	3072

Abstract

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Equations (11)

Journal of Optical Communications and Networking