Abstract. Humanoid robots have a large number of “extra ” joints, organized in a humanlike fashion with several kinematic chains. In this chapter we describe a method of motion planning that is based on an artificial potential field approach (Passive Motion Paradigm) combined with terminal-attractor dynamics. No matrix inversion is necessary and the computational mechanism does not crash near kinematic singularities or when the robot is asked to achieve a final pose that is outside its intrinsic workspace: what happens, in this case, is the gentle degradation of performance that characterizes humans in the same situations. Moreover, the remaining error at equilibrium is a valuable information for triggering a reasoning process and the searc...
International audienceThe essence of humanoid robots is their ability to reproduce human skills in l...
To produce even the simplest human-like behaviors, a humanoid robot must be able to see, act, and re...
Despite many efforts, balance control of humanoid robots in the presence of unforeseen external or i...
Thanks to their human-like structure, humanoid robots have the potential for accomplishing complex t...
As robots are starting to become part of our daily lives, they must be able to cooperate in a natura...
For a matter of efficiency and robustness, it is often better to use a team of robots instead of a s...
The goal of this thesis is to develop motion planning algorithms for human-like figures that take in...
To enable a robotic assistant to autonomously reach for and transport objects while avoiding obstacl...
Nous proposons une approche de planification unifiée pour robots humanoïdes réalisant des tâches de ...
This master thesis presents a new planning framework for multi-contact interaction of humanoid robot...
Walking is a core task for humanoid robots. Most existing walking controllers fall into one of two c...
We extend the attractor dynamics approach to generate goal-directed movement of a redundant, anthrop...
International audienceThis paper presents a computational approach for transferring principles of hu...
Abstract—Nature has developed methods for controlling the movements of organisms with many degrees o...
2018-07-26In this work, we explore computationally lightweight optimization-based methods for planni...
International audienceThe essence of humanoid robots is their ability to reproduce human skills in l...
To produce even the simplest human-like behaviors, a humanoid robot must be able to see, act, and re...
Despite many efforts, balance control of humanoid robots in the presence of unforeseen external or i...
Thanks to their human-like structure, humanoid robots have the potential for accomplishing complex t...
As robots are starting to become part of our daily lives, they must be able to cooperate in a natura...
For a matter of efficiency and robustness, it is often better to use a team of robots instead of a s...
The goal of this thesis is to develop motion planning algorithms for human-like figures that take in...
To enable a robotic assistant to autonomously reach for and transport objects while avoiding obstacl...
Nous proposons une approche de planification unifiée pour robots humanoïdes réalisant des tâches de ...
This master thesis presents a new planning framework for multi-contact interaction of humanoid robot...
Walking is a core task for humanoid robots. Most existing walking controllers fall into one of two c...
We extend the attractor dynamics approach to generate goal-directed movement of a redundant, anthrop...
International audienceThis paper presents a computational approach for transferring principles of hu...
Abstract—Nature has developed methods for controlling the movements of organisms with many degrees o...
2018-07-26In this work, we explore computationally lightweight optimization-based methods for planni...
International audienceThe essence of humanoid robots is their ability to reproduce human skills in l...
To produce even the simplest human-like behaviors, a humanoid robot must be able to see, act, and re...
Despite many efforts, balance control of humanoid robots in the presence of unforeseen external or i...