Closed-Loop Integrated Sensing, Communication, and Control for Efficient Drone Flight

TL;DR

This paper introduces a closed-loop integrated sensing, communication, and control approach for drone trajectory tracking, addressing channel uncertainties and resource constraints to improve safety and accuracy.

Contribution

It develops a theoretical framework and optimization algorithm for resource allocation in ISCC systems, ensuring stability and minimizing tracking errors under practical constraints.

Findings

System stability depends critically on control resource allocation.

Tracking error is linearly related to sensing accuracy once stability is achieved.

The proposed scheme achieves decimeter-level accuracy, outperforming baseline GNSS methods.

Abstract

Low-altitude wireless networks (LAWN) require drones to follow specific trajectories controlled by ground base stations (GBSs). However, given complex low-altitude channel conditions and limited spectrum and power resources, sensing errors and wireless link unreliability cannot be ignored, leading to trajectory deviations that threaten flight safety. To address this issue, this paper proposes an integrated sensing-communication-control (ISCC) closed-loop trajectory tracking approach, aiming to reveal the coupling mechanisms among communication, sensing, and control during drone flight. In detail, we incorporate sensing errors in trajectory state estimation, packet losses in control command transmission, and finite blocklength transmission effects into the closed-loop dynamics. First, through theoretical analysis, we identify the dominant role of the time-frequency resources allocated to control in ensuring system stability and derive a lower bound on the resources required to guarantee stable operation. Second, to minimize tracking error, we formulate a time-frequency resource allocation optimization problem for the sensing, communication, and control components, subject to constraints on communication rate and closed-loop stability. Accordingly, a solution algorithm based on successive convex approximation is proposed. Third, simulation results indicate that once stability is ensured, system performance is primarily determined by sensing accuracy, with the trajectory tracking error exhibiting an approximately linear dependence on the position error bound. Finally, it is shown that the proposed ISCC scheme avoids trajectory divergence under FBL transmission compared with ISCC designs ignoring control packet loss, and could achieve decimeter-level average tracking accuracy, reducing the error to only 17.37% of that observed in the baseline global navigation satellite system scheme.