Shared Sky, Shared Spectrum: Coordinated Satellite-5G Networks for Low-Altitude Economy

TL;DR

This paper proposes a partially-integrated satellite-5G network framework that uses coarse synchronization and adaptive spectrum sharing to efficiently serve low-altitude aircraft, balancing performance and deployment complexity.

Contribution

It introduces a novel framework for coordinated spectrum sharing in satellite-5G networks with coarse synchronization, leveraging LAA position-awareness and link-feature clustering.

Findings

Significant performance improvements with low overhead.

Adaptive synchronization enhances spectrum sharing efficiency.

Framework enables rapid deployment for low-altitude applications.

Abstract

Driven by both technological development and practical demands, the low-altitude economy relying on low-altitude aircrafts (LAAs) is booming. However, neither satellites nor terrestrial fifth-generation (5G) networks alone can effectively satisfy the communication requirements for ubiquitous lowaltitude coverage. While full integration of satellites and 5G networks offers theoretical benefits, the associated overhead and complexity pose significant challenges for rapid deployment. As a more economical and immediately viable alternative, this paper investigates partially-integrated networks where satellites and 5G systems operate with coarse synchronization yet achieve coordinated spectrum sharing, pooling their capabilities to jointly serve LAAs. Leveraging the inherent position-awareness of LAAs, we propose a framework for joint time-frequency spectrum sharing with an adaptive synchronization time scale, where only large-scale channel state information (CSI) is required. To avoid solving the NP-hard optimization problem directly, link-feature-aided clustering is employed following a divide-andconquer strategy. The proposed framework achieves substantial performance gains with low overhead and complexity, enabling swift advancement of low-altitude applications while paving the way for future integrated satellite-terrestrial network evolution.