Add to ORKGTerrain traversability analysis plays a major role in ensuring safe robotic navigation in unstructured environments. However, real-time constraints frequently limit the accuracy of online tests especially in scenarios where realistic robot-terrain interactions are complex to model. In this context, we propose a deep learning framework trained in an end-to-end fashion from elevation maps and trajectories to estimate the occurrence of failure events. The network is first trained and tested in simulation over synthetic maps generated by the OpenSimplex algorithm. The prediction performance of the Deep Learning framework is illustrated by being able to retain over 94% recall of the original simulator at 30% of the computational time. Finally, t...
Autonomous 3D rough terrain navigation requires a mobile robot to maneuver cluttered environments th...
This thesis is focused on deep reinforcement learning for mobile robot navigation in unstructured en...
This paper is an initial endeavor to bridge the gap between powerful Deep Reinforcement Learning met...
The ability to have unmanned ground vehicles navigate unmapped off-road terrain has high impact pote...
Despite the progress in legged robotic locomotion, autonomous navigation in unknown environments rem...
We present a method that uses high-resolution topography data of rough terrain, and ground vehicle s...
Mobile ground robots operating on unstructured terrain must predict which areas of the environment t...
We present a method that uses high-resolution topography data of rough terrain, and ground vehicle s...
We present a method that uses high-resolution topography data of rough terrain, and ground vehicle s...
We present a method that uses high-resolution topography data of rough terrain, and ground vehicle s...
We present a method that uses high-resolution topography data of rough terrain, and ground vehicle s...
We present a method that uses high-resolution topography data of rough terrain, and ground vehicle s...
Mobile robots have a promising application prospect as they can assist or replace humans to perform...
Robots that autonomously navigate real-world 3D cluttered environments need to safely traverse terra...
Accurate and complete terrain maps enhance the awareness of autonomous robots and enable safe and op...
Autonomous 3D rough terrain navigation requires a mobile robot to maneuver cluttered environments th...
This thesis is focused on deep reinforcement learning for mobile robot navigation in unstructured en...
This paper is an initial endeavor to bridge the gap between powerful Deep Reinforcement Learning met...
The ability to have unmanned ground vehicles navigate unmapped off-road terrain has high impact pote...
Despite the progress in legged robotic locomotion, autonomous navigation in unknown environments rem...
We present a method that uses high-resolution topography data of rough terrain, and ground vehicle s...
Mobile ground robots operating on unstructured terrain must predict which areas of the environment t...
We present a method that uses high-resolution topography data of rough terrain, and ground vehicle s...
We present a method that uses high-resolution topography data of rough terrain, and ground vehicle s...
We present a method that uses high-resolution topography data of rough terrain, and ground vehicle s...
We present a method that uses high-resolution topography data of rough terrain, and ground vehicle s...
We present a method that uses high-resolution topography data of rough terrain, and ground vehicle s...
Mobile robots have a promising application prospect as they can assist or replace humans to perform...
Robots that autonomously navigate real-world 3D cluttered environments need to safely traverse terra...
Accurate and complete terrain maps enhance the awareness of autonomous robots and enable safe and op...
Autonomous 3D rough terrain navigation requires a mobile robot to maneuver cluttered environments th...
This thesis is focused on deep reinforcement learning for mobile robot navigation in unstructured en...
This paper is an initial endeavor to bridge the gap between powerful Deep Reinforcement Learning met...