Traversability-aware Adaptive Optimization for Robust Navigation in Extreme Mountainous Terrain

A traversability-aware navigation framework that integrates apparent traversability from exteroceptive sensors and relative traversability from proprioceptive sensors to generate an optimal path and adaptively control the robot's velocity for robust navigation in extreme mountainous terrain.

The paper presents a traversability-aware navigation framework called TAO (Traversability-aware Adaptive Optimization) for robots navigating in extreme mountainous terrain. The key aspects of the framework are: Terrain Assessment: Apparent Traversability (Mτ): Computed using exteroceptive sensor data (height map, normal map) to capture the geometric features of the terrain, such as slope, sparsity, and bumpiness. Regional Constraints (Mγ): Identified hazardous regions based on the designed terrain features. Relative Traversability (Ψτ): Calculated using both exteroceptive and proprioceptive sensor data to consider the ground-robot interaction, specifically the fluctuation of the robot's pitching angle. Planning and Control: Traversability-aware Path Optimization: An adaptive sampling scheme and path optimization method are integrated into a sampling-based search tree to generate a feasible path that circumvents undulating and risky regions. Adaptive Control Optimization: A nonlinear model predictive controller (NMPC) is formulated to prevent the robot from getting stuck or damaged while following the planned path. It utilizes both apparent and relative traversability to dynamically adjust the robot's velocity. The experiments conducted in simulation with 27 diverse types of mountainous terrain and in the real world demonstrate the robustness of the proposed TAO framework. Compared to other methods, TAO achieves up to 16% improvement in both effectiveness and stability through hazard avoidance and dynamic velocity adjustments that consider ground-robot interaction.

The robot's linear velocity ζ and angular velocity ω are used as control variables in the optimization process. The robot's state s = (x, y, θ) is predicted using a skid-steering model.

"We separate traversability into apparent traversability and relative traversability, then incorporate these distinctions in the optimization process of sampling-based planning and motion predictive control." "Our method enables the robots to execute the desired behaviors more accurately while avoiding hazardous regions and getting stuck."