Abstract
Suitable composable data center networks (DCNs) are essential to support the disaggregation of compute components in highly efficient next generation data centers (DCs). However, designing such composable DCNs can be challenging. A composable DCN that adopts a full mesh backplane between disaggregated compute components within a rack and employs dedicated interfaces on each point-to-point link is wasteful and expensive. In this paper, we propose and describe two (i.e., electrical, and electrical-optical) variants of a network for composable DC (NetCoD). NetCoD adopts a targeted design to reduce the number of transceivers required when a mesh physical backplane is deployed between disaggregated compute components in the same rack. The targeted design leverages optical communication techniques and components to achieve this with minimal or no network performance degradation. We formulate a MILP model to evaluate the performance of both variants of NetCoD in rack-scale composable DCs that implement different forms of disaggregation. The electrical-optical variant of NetCoD achieves similar performance as a reference network while utilizing fewer transceivers per compute node. The targeted adoption of optical technologies by both variants of NetCoD achieves greater (4 - 5 times greater) utilization of available network throughput than the reference network which implements a generic design. Under the various forms of disaggregation considered, both variant of NetCoD achieve near-optimal compute energy efficiency in the composable DC while satisfying both compute and network constraints. This is because marginal concession of optimal compute energy efficiency is often required to achieve overall optimal energy efficiency in composable DCs.
Highlights
Data centers (DCs) are pivotal infrastructures which support on-demand access to computing capacity at scale
In contrast to the general-purpose design employed when mesh physical topology is employed in the intra-rack networks of composable DCs, a more targeted design is adopted in network for composable DC (NetCoD)
Using a MILP model for capacitated networks, we compare the performance of both variants of NetCoD to the performance of a reference network topology in a DC with multiple racks
Summary
Data centers (DCs) are pivotal infrastructures which support on-demand access to computing capacity at scale. NETWORK TOPOLOGIES FOR COMPOSABLE DC High capacity and ultra-low latency network topologies are required to interconnect nodes in a composable DC following physical, logical and hybrid disaggregation of computing components Such networks support the orchestration and management software of composable DCs to optimally utilize disaggregated components. A variant of the network for composable DCs proposed in this paper is a hybrid topology that demonstrates the strategic use of electrical and optical switches for optimal efficiency. NETWORK DESCRIPTION Network for Composable DCs (NetCoD) is a converged network topology that implements the distributed switch architecture It leverages optical communication technologies and silicon photonics to support high-speed and low latency communication in composable DCs. Two variants of NetCoD are described in this paper i.e., electrical, and electrical-optical variants. Because each optical link establishes a dedicated point-to-point communication link between unique node pairs in the rack, space division multiplexing (SDM) enables wavelength reuse on the optical backplane within the same rack
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