Add to ORKGAbstract — We present a novel algorithm to compute collision-free trajectories in dynamic environments. Our approach is general and does not require a priori knowledge about the obstacles or their motion. We use a replanning framework that interleaves optimization-based planning with execution. Furthermore, we describe a parallel formulation that exploits a high number of cores on commodity graphics processors (GPUs) to compute a high-quality path in a given time interval. We derive bounds on how parallelization can improve the responsiveness of the planner and the quality of the trajectory. I
A key requirement of autonomous vehicles is the capability to safely navigate in their environment. ...
A key requirement of autonomous vehicles is the capability to safely navigate in their environment. ...
A parallel version of the traditional grid based cost-to-go function generation algorithm used in ro...
Abstract We present a novel algorithm to compute collision-free trajectories in dynamic environ-ment...
We present a novel algorithm to compute collision-free trajectories in dynamic environments. Our app...
We present a novel algorithm to compute collision-free tra-jectories in dynamic environments. Our ap...
We present novel randomized algorithms for solving global motion planning problems that exploit the ...
We present novel randomized algorithms for solving global motion planning problems that exploit the ...
We present novel randomized algorithms for solving global motion planning problems that exploit the ...
We present parallel algorithms to accelerate collision queries for sample-based motion planning. Our...
We present parallel algorithms to accelerate collision queries for sample-based motion planning. Our...
Abstract—We present a realtime GPU-based motion plan-ning algorithm for robot task executions. Many ...
We present a method to plan collision free paths for robots with any number of degrees of freedom in...
For decades, humans have dreamed of making cars that could drive themselves, so that travel would be...
A key requirement of autonomous vehicles is the capability to safely navigate in their environment. ...
A key requirement of autonomous vehicles is the capability to safely navigate in their environment. ...
A key requirement of autonomous vehicles is the capability to safely navigate in their environment. ...
A parallel version of the traditional grid based cost-to-go function generation algorithm used in ro...
Abstract We present a novel algorithm to compute collision-free trajectories in dynamic environ-ment...
We present a novel algorithm to compute collision-free trajectories in dynamic environments. Our app...
We present a novel algorithm to compute collision-free tra-jectories in dynamic environments. Our ap...
We present novel randomized algorithms for solving global motion planning problems that exploit the ...
We present novel randomized algorithms for solving global motion planning problems that exploit the ...
We present novel randomized algorithms for solving global motion planning problems that exploit the ...
We present parallel algorithms to accelerate collision queries for sample-based motion planning. Our...
We present parallel algorithms to accelerate collision queries for sample-based motion planning. Our...
Abstract—We present a realtime GPU-based motion plan-ning algorithm for robot task executions. Many ...
We present a method to plan collision free paths for robots with any number of degrees of freedom in...
For decades, humans have dreamed of making cars that could drive themselves, so that travel would be...
A key requirement of autonomous vehicles is the capability to safely navigate in their environment. ...
A key requirement of autonomous vehicles is the capability to safely navigate in their environment. ...
A key requirement of autonomous vehicles is the capability to safely navigate in their environment. ...
A parallel version of the traditional grid based cost-to-go function generation algorithm used in ro...