Zhu, Jie; Xu, Tianheng; Wang, Chao; Ying, Kai; Zhou, Ting; Zhang, Haijun; Hu, Honglin

IEEE INTERNET OF THINGS JOURNAL

2025, 11,

Zhu, Jie; Xu, Tianheng; Wang, Chao; Ying, Kai; Zhou, Ting; Zhang, Haijun; Hu, Honglin

With the sixth-generation mobile communication technology (6G) experiencing a shift of spatial expansion, the integration of terrestrial architecture and satellites has become one core feature of 6G. While the scarcity of spectrum resources has become a significant challenge hindering the advancement of integrated satellite-terrestrial networks, it is crucial to push the development of effective strategies to optimize spectrum utilization. This letter introduces a flexible spectrum sensing technique in the nonorthogonal multiple access (NOMA) uplink system for low-earth orbit (LEO) satellite-terrestrial communications, striking an optimal balance between under-sensing and over-sensing. Confronted with diverse complicated scenarios of multisatellite coverage, we conceive the operational principles and derive the sensing thresholds, exploiting spectrum holes and mitigating the fluctuation of false alarms. Notably, numerical outcomes showcase that the proposed technique outperforms the benchmarks, achieving a maximum throughput gain of 61.5% in dynamic communication environments.