Network Slice Embedding over Space Division Multiplexed Elastic Optical Networks

TL;DR

This paper introduces a novel resource allocation scheme for SDM EONs that integrates compute placement with spectrum allocation, significantly improving efficiency and acceptance ratios.

Contribution

It proposes the WMSM scheme, a sequential, coupled approach to joint compute and spectrum resource management in SDM EONs, addressing a key gap in prior studies.

Findings

WMSM increases acceptance ratios by up to 27% under high load.

It achieves up to 47% lower total provisioning cost.

The scheme enables more flexible and efficient resource placement.

Abstract

Network slicing over space division multiplexed elastic optical networks (SDM EONs) enables efficient multiservice provisioning on a shared optical substrate. However, embedding such slices requires coordinated spectrum and compute resource management under dynamic traffic, which most existing RMCSA studies treat independently. This paper focuses on the network slice embedding problem over space division multiplexed elastic optical networks (SDM EONs), aiming to develop efficient resource allocation strategies that ensure both high utilization and reliable service performance. While prior studies have investigated routing, modulation format, core, and spectrum allocation (RMCSA), they typically consider these dimensions separately from compute placement. To address this gap, this paper proposes a Waypoint Assisted Multi Segment Slice Mapping (WMSM) scheme, which integrates compute placement with spectrum allocation in a sequential but coupled manner to enable more flexible resource placement and improved spectrum efficiency. Numerical results show that WMSM improves acceptance ratios by up to 27% under high load conditions, while achieving up to 47% lower total provisioning cost relative to the baseline strategy. These results highlight the benefits of integrated compute spectrum provisioning and provide design insights for scalable, compute aware optical slice mapping.