From Small to Large: Clos Network for Scaling All-Optical Switching

TL;DR

This paper proposes a Clos network architecture for scalable all-optical switching, offering improved performance and flexibility over traditional architectures for high-capacity optical networks and datacenter interconnects.

Contribution

It introduces a next-generation Clos-based ROADM architecture that outperforms traditional Spanke-based designs and demonstrates its application in large-scale all-optical datacenter networks.

Findings

Better blocking performance than traditional architectures

Lower element and fiber complexity

Enhanced flexibility for multicast services

Abstract

To cater to the demands of our rapidly growing Internet traffic, backbone networks need high-degree reconfigurable optical add/drop multiplexers (ROADMs) to simultaneously support multiple pairs of bi-directional fibers on each link. However, the traditional ROADM architecture based on the Spanke network is too complex to be directly scaled up to construct high-degree ROADMs. In addition, the widely deployed Spine-Leaf datacenter networks (DCNs) based on electrical switches consume too much power and exhibit high packet latency. Because of these issues, Clos networks are considered as promising alternatives for constructing large-scale ROADMs and all-optical DCNs. In this article, we look at a next-generation Clos-based ROADM architecture and show that it indeed provides better blocking performance with lower element and fiber complexities compared with a traditional Spanke-based ROADM architecture. We also discuss the application of a Clos network in all-optical DCNs to show that it can be used to effectively construct large-scale DCNs with significantly greater flexibility in supporting a variety of multicast services and in combining different network topologies.