Semantic-Aware Trajectory Planning for UAV in Dynamic Environments

Van Hung Nguyen; The Tien Nguyen; Tran Thang Le; Viet Hong Le

doi:10.14313/jamris-2026-011

Abstract

Generating trajectories that leverage semantic information to guide a UAV safely and accurately to its destination in a dynamic environment remains an open problem. In the existing literature, semantics have been used to prioritize certain areas – either to guide the UAV through or to avoid them-forspecific objectives, such as reducing errors in visual-inertial SLAM (VI-SLAM). However, prior work typically assumes a static environment when performing collision checking, even in cluttered and dynamic settings.

We propose a two-stage workflow: The first stage performs semantic-aware pathfinding. The second stage optimizes the resulting path, incorporating kinematic constraints and performing collision checking that accounts for obstacle motion, while still ensuring real-time performance.

To the best of our knowledge, this is the first approach that generates UAV trajectories by simultaneously leveraging semantic information and accounting for cluttered, dynamic environments. A summary video is available at https://youtu.be/I5w6AP7HThU.

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Semantic-Aware Trajectory Planning for UAV in Dynamic Environments

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