Knowledge of terrain's physical properties inferred from color images can aid in making efficient robotic locomotion plans. However, unlike image classification, it is unintuitive for humans to label image patches with physical properties. Without labeled data, building a vision system that takes as input the observed terrain and predicts physical properties remains challenging. We present a method that overcomes this challenge by self-supervised labeling of images captured by robots during real-world traversal with physical property estimators trained in simulation. To ensure accurate labeling, we introduce Active Sensing Motor Policies (ASMP), which are trained to explore locomotion behaviors that increase the accuracy of estimating physi...
Estimating terrain traversability in off-road environments requires reasoning about complex interact...
In this work, we show how to learn a visual walking policy that only uses a monocular RGB camera and...
We present a self-supervised approach for learning to predict traversable paths for wheeled mobile r...
Legged robots have the potential to traverse diverse and rugged terrain. To find a safe and ...
Quadrupedal robots resemble the physical ability of legged animals to walk through unstructured terr...
Despite the progress in legged robotic locomotion, autonomous navigation in unknown environments rem...
We present TerraPN, a novel method that learns the surface properties (traction, bumpiness, deformab...
Humans and robots would benefit from having rich semantic maps of the terrain in which they operate....
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Mechanical Engineering, 2009.This e...
Robotic technologies will continue to enter new applications in addition to automated manufacturing ...
The equations of motion governing mobile robots are dependent on terrain properties such as the coef...
In recent years, there has been an increased interest in implementing intelligent robotic systems in...
Reinforcement learning (RL) for bipedal locomotion has recently demonstrated robust gaits over moder...
Legged robots promise a clear advantage in unstructured and challenging terrain, scenarios such as d...
Inspired by the digital twinning systems, a novel real-time digital double framework is developed to...
Estimating terrain traversability in off-road environments requires reasoning about complex interact...
In this work, we show how to learn a visual walking policy that only uses a monocular RGB camera and...
We present a self-supervised approach for learning to predict traversable paths for wheeled mobile r...
Legged robots have the potential to traverse diverse and rugged terrain. To find a safe and ...
Quadrupedal robots resemble the physical ability of legged animals to walk through unstructured terr...
Despite the progress in legged robotic locomotion, autonomous navigation in unknown environments rem...
We present TerraPN, a novel method that learns the surface properties (traction, bumpiness, deformab...
Humans and robots would benefit from having rich semantic maps of the terrain in which they operate....
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Mechanical Engineering, 2009.This e...
Robotic technologies will continue to enter new applications in addition to automated manufacturing ...
The equations of motion governing mobile robots are dependent on terrain properties such as the coef...
In recent years, there has been an increased interest in implementing intelligent robotic systems in...
Reinforcement learning (RL) for bipedal locomotion has recently demonstrated robust gaits over moder...
Legged robots promise a clear advantage in unstructured and challenging terrain, scenarios such as d...
Inspired by the digital twinning systems, a novel real-time digital double framework is developed to...
Estimating terrain traversability in off-road environments requires reasoning about complex interact...
In this work, we show how to learn a visual walking policy that only uses a monocular RGB camera and...
We present a self-supervised approach for learning to predict traversable paths for wheeled mobile r...