SafeLand: Safe Autonomous Landing in Unknown Environments with Bayesian Semantic Mapping

TL;DR

SafeLand is a vision-based autonomous landing system for UAVs that uses semantic mapping and Bayesian filtering to identify safe landing spots in unknown environments without prior maps, ensuring high safety and success rates.

Contribution

The paper introduces SafeLand, a novel lightweight, vision-only system for safe autonomous landing that operates in unknown environments using semantic mapping and probabilistic filtering.

Findings

Achieved 70.22% mIoU on semantic segmentation across 20 classes.

Demonstrated 95% success rate in diverse real-world tests.

Zero false negatives in human detection during landing scenarios.

Abstract

Autonomous landing of uncrewed aerial vehicles (UAVs) in unknown, dynamic environments poses significant safety challenges, particularly near people and infrastructure, as UAVs transition to routine urban and rural operations. Existing methods often rely on prior maps, heavy sensors like LiDAR, static markers, or fail to handle non-cooperative dynamic obstacles like humans, limiting generalization and real-time performance. To address these challenges, we introduce SafeLand, a lean, vision-based system for safe autonomous landing (SAL) that requires no prior information and operates only with a camera and a lightweight height sensor. Our approach constructs an online semantic ground map via deep learning-based semantic segmentation, optimized for embedded deployment and trained on a consolidation of seven curated public aerial datasets (achieving 70.22% mIoU across 20 classes), which is further refined through Bayesian probabilistic filtering with temporal semantic decay to robustly identify metric-scale landing spots. A behavior tree then governs adaptive landing, iteratively validates the spot, and reacts in real time to dynamic obstacles by pausing, climbing, or rerouting to alternative spots, maximizing human safety. We extensively evaluate our method in 200 simulations and 60 end-to-end field tests across industrial, urban, and rural environments at altitudes up to 100m, demonstrating zero false negatives for human detection. Compared to the state of the art, SafeLand achieves sub-second response latency, substantially lower than previous methods, while maintaining a superior success rate of 95%. To facilitate further research in aerial robotics, we release SafeLand's segmentation model as a plug-and-play ROS package, available at https://github.com/markus-42/SafeLand.