We present TerraPN, a novel method that learns the surface properties (traction, bumpiness, deformability, etc.) of complex outdoor terrains directly from robot-terrain interactions through self-supervised learning, and uses it for autonomous robot navigation. Our method uses RGB images of terrain surfaces and the robot's velocities as inputs, and the IMU vibrations and odometry errors experienced by the robot as labels for self-supervision. Our method computes a surface cost map that differentiates smooth, high-traction surfaces (low navigation costs) from bumpy, slippery, deformable surfaces (high navigation costs). We compute the cost map by non-uniformly sampling patches from the input RGB image by detecting boundaries between surfaces ...
We present a novel system, AdVENTR for autonomous robot navigation in unstructured outdoor environme...
A classifier training methodology is presented for Kapvik, a micro-rover prototype. A simulated ligh...
This paper describes a computationally inexpensive approach to learning and identification of maneuv...
Autonomous navigation by a mobile robot through L natural, unstructured terrain is one of the premie...
Accurate and complete terrain maps enhance the awareness of autonomous robots and enable safe and op...
Estimating terrain traversability in off-road environments requires reasoning about complex interact...
Legged robots have the potential to traverse diverse and rugged terrain. To find a safe and ...
Abstract — In mobile robotics, there are often features that, while potentially powerful for improvi...
Despite the progress in legged robotic locomotion, autonomous navigation in unknown environments rem...
Knowledge of terrain's physical properties inferred from color images can aid in making efficient ro...
We present a self-supervised approach for learning to predict traversable paths for wheeled mobile r...
Accurate and complete terrain maps enhance the awareness of autonomous robots and enable safe and op...
A key challenge in off-road navigation is that even visually similar terrains or ones from the same ...
Mobile robots, such as vacuum cleaning robots and robotic lawn mowers, have become part of our daily...
We propose GANav, a novel group-wise attention mechanism to identify safe and navigable regions in o...
We present a novel system, AdVENTR for autonomous robot navigation in unstructured outdoor environme...
A classifier training methodology is presented for Kapvik, a micro-rover prototype. A simulated ligh...
This paper describes a computationally inexpensive approach to learning and identification of maneuv...
Autonomous navigation by a mobile robot through L natural, unstructured terrain is one of the premie...
Accurate and complete terrain maps enhance the awareness of autonomous robots and enable safe and op...
Estimating terrain traversability in off-road environments requires reasoning about complex interact...
Legged robots have the potential to traverse diverse and rugged terrain. To find a safe and ...
Abstract — In mobile robotics, there are often features that, while potentially powerful for improvi...
Despite the progress in legged robotic locomotion, autonomous navigation in unknown environments rem...
Knowledge of terrain's physical properties inferred from color images can aid in making efficient ro...
We present a self-supervised approach for learning to predict traversable paths for wheeled mobile r...
Accurate and complete terrain maps enhance the awareness of autonomous robots and enable safe and op...
A key challenge in off-road navigation is that even visually similar terrains or ones from the same ...
Mobile robots, such as vacuum cleaning robots and robotic lawn mowers, have become part of our daily...
We propose GANav, a novel group-wise attention mechanism to identify safe and navigable regions in o...
We present a novel system, AdVENTR for autonomous robot navigation in unstructured outdoor environme...
A classifier training methodology is presented for Kapvik, a micro-rover prototype. A simulated ligh...
This paper describes a computationally inexpensive approach to learning and identification of maneuv...