Modular WSS-based OXCs for Large-Scale Optical Networks

TL;DR

This paper introduces a modular design for wavelength selective switch-based optical cross-connects (OXCs) that enhances scalability and reduces cabling complexity for large-scale optical networks.

Contribution

A novel three-phase modular construction method for WSS-based OXCs, improving scalability and physical-layer performance over traditional designs.

Findings

Modular OXCs are nonblocking at each wavelength.

The design reduces cabling complexity.

Physical-layer performance remains acceptable.

Abstract

The explosive growth of broadband applications calls for large-scale optical cross-connects (OXCs). However, the classical wavelength selective switch (WSS) based OXC is not scalable in terms of the size of employed WSSs and the cabling complexity. To solve this problem, we propose a three-phase approach to construct a modular WSS-based OXC. In phase 1, we factorize the interconnection network between the input stage and the output stage of the traditional OXC into a set of small-size interconnection networks. In phase 2, we decompose each WSS into a two-stage cascaded structure of small-size WSSs. In phase 3, we combine the small-size interconnection networks with the small-size WSSs to form a set of small-size OXC modules. At last, we obtain a modular OXC, which is a network of small-size OXCs. Similar to the classical OXC, the modular OXC is nonblocking at each wavelength and possesses a self-routing property. Our analysis shows that the modular OXC has small cabling complexity and acceptable physical-layer performance.