MCF-SMF Hybrid Low-Latency Circuit-Switched Optical Network for Disaggregated Data Centers

Saljoghei, Arsalan; Yuan, Hui; Mishra, Vishram; Enrico, Michael; Parsons, Nick; Kochis, Craig; Dobbelaere, P. De; Theodoropoulos, Dimitris; Pnevmatikatos, Dionisios; Syrivelis, Dimitris; Reale, Andrea; Hayashi, Tetsuya; Nakanishi, Tetsuya; Zervas, Georgios

doi:10.1109/jlt.2019.2920354

Cited by 10 publications

(5 citation statements)

References 17 publications

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“…Compared with milliseconds switching time in an Optical Circuit Switch (OCS)based network in [21] and microseconds switching time in a micro-ring resonator-based network in [23], the implemented NOS-based decomposed computing prototype can achieve nanoseconds switching time (43.4 ns), while keeping a stable interconnect link with none packet loss. These assessment results demonstrate the superiority of the proposed optical decomposed computing network based on NOS with respect to existing works.…”

Section: Discussionmentioning

confidence: 99%

“…A Software-Defined Networking (SDN)-based orchestration plane is designed and experimentally implemented for a decomposed computing architecture in [19] with hybrid optical switches. Decomposed architectures based on optical switches were proposed and experimentally investigated in [20,21], exploiting high aggregation bandwidths and transparent switching; however, the high switching delay (milliseconds) of the optical switch technology cannot provide nanoseconds scale communication between processor and memory cubes. An optically connected memory architecture was demonstrated in [22,23] based on micro-ring resonator switches and the Aurora 64B/66B protocol, which achieved an optical switching time of hundreds of microseconds.…”

Section: Related Workmentioning

confidence: 99%

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A Novel Decomposed Optical Architecture for Satellite Terrestrial Network Edge Computing

et al. 2022

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Aiming at providing a high-performance terrestrial network for edge computing in satellite networks, we experimentally demonstrate a high bandwidth and low latency decomposed optical computing architecture based on distributed Nanoseconds Optical Switches (NOS). Experimental validation of the decomposed computing network prototype employs a four-port NOS to interconnect four processor/memory cubes. The SOA-based optical gates provide an ON/OFF ratio greater than 60 dB, enabling none-error transmission at a Bit Error Rate (BER) of 1 × 10−9. An end-to-end access latency of 122.3 ns and zero packet loss are obtained in the experimental assessment. Scalability and physical performance considering signal impairments when increasing the NOS port count are also investigated. An output OSNR of up to 30.5 dB and an none-error transmission with 1.5 dB penalty is obtained when scaling the NOS port count to 64. Moreover, exploiting the experimentally measured parameters, the network performance of NOS-based decomposed computing architecture is numerically assessed under larger network scales. The results indicate that, under a 4096-cube network scale, the NOS-based decomposed computing architecture achieves 148.5 ns end-to-end latency inside the same rack and zero packet loss at a link bandwidth of 40 Gb/s.

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Section: Discussionmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

A Novel Decomposed Optical Architecture for Satellite Terrestrial Network Edge Computing

et al. 2022

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“…Due to the low latencies and high bit-rates that are required for hardware module to hardware module communications (up to several hundreds of Gb/s in the case of CPU-to-CPU or CPU-to-memory), high performance technologies are required. In this regard, optical network technologies are seen as prime candidates for the interconnection of the several hardware blades [6], [8]. Several optical switches as well as fiber links enable the interconnection within and between the multiple racks hosting the blades.…”

Section: Disaggregated Compute Sites For ML Application Deploymentmentioning

confidence: 99%

On the challenges of optical disaggregated data center networking for ML/AI applications

Spadaro,

Pages Cruz,

Agraz

2024

Next-Generation Optical Communication: Components, Sub-Systems, and Systems XIII

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The rising of applications with intense requirements in data volumes, storage space and CPU/GPU utilization, such as Machine Learning/Artificial Intelligence (ML/AI) applications, imposes different challenges on the Data Center Network design and operation. When compared to traditional data centers infrastructures, the recent explored disaggregated optical data center concept may bring multiple benefits in terms of optimized usage of the IT and network resources. Nevertheless, at the same time, it also brings some technical challenges. In such context, the paper discusses both data and control architectural solutions for optical disaggregated data centers for ML/AI applications, focusing on their benefits but also on the associated complexities.

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“…Obviously, SDM transmission has a great potential to address capacity requirement for the DC disaggregation. In the recently proposed resource centric disaggregated data center architecture [112], the integration of MCF-based transceivers, fibers, and optical switches is experimentally validated. The results show the benefits of SDM in terms of capacity, power consumption, latency and space efficiency for interconnecting disaggregated IT elements.…”

Section: Network Aspects: Architectures and Resource Allocation Strategiesmentioning

confidence: 99%

Enabling Technologies for Optical Data Center Networks: Spatial Division Multiplexing

Westergren

Chen

Agrell

et al. 2020

J. Lightwave Technol.

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With the continuously growing popularity of cloud services, the traffic volume inside the data centers is dramatically increasing. As a result, a scalable and efficient infrastructure for data center networks (DCNs) is required. The current optical DCNs using either individual fibers or fiber ribbons are costly, bulky, hard to manage, and not scalable. Spatial division multiplexing (SDM) based on multicore or multimode (few-mode) fibers is recognized as a promising technology to increase the spatial efficiency for optical DCNs, which opens a new way towards high capacity and scalability. This tutorial provides an overview of the components, transmission options, and interconnect architectures for SDM-based DCNs, as well as potential technical challenges and future directions. It also covers the co-existence of SDM and other multiplexing techniques, such as wavelength-division multiplexing and flexible spectrum multiplexing, in optical DCNs.

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MCF-SMF Hybrid Low-Latency Circuit-Switched Optical Network for Disaggregated Data Centers

Cited by 10 publications

References 17 publications

A Novel Decomposed Optical Architecture for Satellite Terrestrial Network Edge Computing

A Novel Decomposed Optical Architecture for Satellite Terrestrial Network Edge Computing

On the challenges of optical disaggregated data center networking for ML/AI applications

Enabling Technologies for Optical Data Center Networks: Spatial Division Multiplexing

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