Optically connected memory for disaggregated data centers

Jorge Gonzalez; Mauricio G. Palma; Maarten Hattink; Ruth Rubio-Noriega; Lois Orosa; Onur Mutlu; Keren Bergman; Rodolfo Azevedo

doi:10.1016/j.jpdc.2022.01.013

Optically connected memory for disaggregated data centers

Jorge Gonzalez, Mauricio G. Palma, Maarten Hattink, Ruth Rubio-Noriega, Lois Orosa, Onur Mutlu, Keren Bergman, Rodolfo Azevedo

Departamento de Ciencia de la Computación

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

12 Citas (Scopus)

Resumen

Recent advances in integrated photonics enable the implementation of reconfigurable, high-bandwidth, and low energy-per-bit interconnects in next-generation data centers. We propose and evaluate an Optically Connected Memory (OCM) architecture that disaggregates the main memory from the computation nodes in data centers. OCM is based on micro-ring resonators (MRRs), and it does not require any modification to the DRAM memory modules. We calculate energy consumption from real photonic devices and integrate them into a system simulator to evaluate performance. Our results show that (1) OCM is capable of interconnecting four DDR4 memory channels to a computing node using two fibers with 1.02 pJ energy-per-bit consumption and (2) OCM performs up to 5.5× faster than a disaggregated memory with 40G PCIe NIC connectors to computing nodes.

Idioma original	Inglés
Páginas (desde-hasta)	300-312
Número de páginas	13
Publicación	Journal of Parallel and Distributed Computing
Volumen	163
DOI	https://doi.org/10.1016/j.jpdc.2022.01.013
Estado	Publicada - may. 2022

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abstract = "Recent advances in integrated photonics enable the implementation of reconfigurable, high-bandwidth, and low energy-per-bit interconnects in next-generation data centers. We propose and evaluate an Optically Connected Memory (OCM) architecture that disaggregates the main memory from the computation nodes in data centers. OCM is based on micro-ring resonators (MRRs), and it does not require any modification to the DRAM memory modules. We calculate energy consumption from real photonic devices and integrate them into a system simulator to evaluate performance. Our results show that (1) OCM is capable of interconnecting four DDR4 memory channels to a computing node using two fibers with 1.02 pJ energy-per-bit consumption and (2) OCM performs up to 5.5× faster than a disaggregated memory with 40G PCIe NIC connectors to computing nodes.",

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doi = "10.1016/j.jpdc.2022.01.013",

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AU - Gonzalez, Jorge

AU - G. Palma, Mauricio

AU - Hattink, Maarten

AU - Rubio-Noriega, Ruth

AU - Orosa, Lois

AU - Mutlu, Onur

AU - Bergman, Keren

AU - Azevedo, Rodolfo

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AB - Recent advances in integrated photonics enable the implementation of reconfigurable, high-bandwidth, and low energy-per-bit interconnects in next-generation data centers. We propose and evaluate an Optically Connected Memory (OCM) architecture that disaggregates the main memory from the computation nodes in data centers. OCM is based on micro-ring resonators (MRRs), and it does not require any modification to the DRAM memory modules. We calculate energy consumption from real photonic devices and integrate them into a system simulator to evaluate performance. Our results show that (1) OCM is capable of interconnecting four DDR4 memory channels to a computing node using two fibers with 1.02 pJ energy-per-bit consumption and (2) OCM performs up to 5.5× faster than a disaggregated memory with 40G PCIe NIC connectors to computing nodes.

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KW - Data-centers

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Optically connected memory for disaggregated data centers

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