Sensing Capacity for Integrated Sensing and Communication Systems in Low-Altitude Economy
Jiahua Wan, Hong Ren, Cunhua Pan, Zhenkun Zhang, Songtao Gao, Yiming Yu, Chengzhong Wang
Abstract
The burgeoning significance of the low-altitude economy (LAE) has garnered considerable interest, largely fuelled by the widespread deployment of unmanned aerial vehicles (UAVs). To tackle the challenges associated with the detection of unauthorized UAVs and the efficient scheduling of authorized UAVs, this letter introduces a novel performance metric, termed sensing capacity, for integrated sensing and communication (ISAC) systems. This metric, which quantifies the capability of a base station (BS) to detect multiple UAVs simultaneously, leverages signal-to-noise ratio (SNR) and probability of detection (PD) as key intermediate variables. Through mathematical derivations, we can derive a closed-form solution for the maximum number of UAVs that can be detected by the BS while adhering to a specific SNR constraint. An approximate solution based on PD constraints is proposed to facilitate the efficient determination of the threshold for the maximum number of detectable UAVs. To generalize the analysis, we extend our investigation to practical scenarios with closely-spaced UAVs, incorporating inter-UAV interference effects. The accuracy of this analytical approach is verified through extensive simulation results.