textThe problem of performing complex maneuvers in challenging terrains is crucial to the advancement of legged robots and assistive devices, yet little progress has been made in exploring practical solutions to operate in these environments. In this thesis, we tackle the problem by developing strategies to predict a robot's center of mass (CoM) behavior based on contact constraints, and any arbitrary CoM path for situations in which the system has single or multiple points of contact through which external reaction forces may be applied. Our method consists of first leveraging previous work on multi-contact dynamics to derive reaction force behavior from internal tension force profiles and kinematic CoM trajectories. We then st...
Anthropomorphic locomotion is a complex process that involves a very large number of degrees of free...
In this letter, we propose a two-stage strategy for optimal control problems of robotic mechanical s...
International audiencePlanning, adapting and executing multi-contact locomotion movements on legged ...
The fundamental objective of robotics is to enhance the productivity of humans while interacting in ...
For legged robots, generating dynamic and versatile motions is essential for interacting with comple...
Although the problem of dynamic locomotion in very rough terrain is crit-ical to the advancement of ...
Incremental progress in humanoid robot locomotion over the years has achieved essential capabilities...
International audienceThe essence of humanoid robots is their ability to reproduce human skills in l...
This paper presents a practical solution to the problem of multi-legged robot stability moving on un...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Electrical Engineering and Comp...
International audienceWe present a multi-contact walking pattern generator based on preview-control ...
Humanoids' abilities to navigate uneven terrain make them well-suited for disaster response efforts,...
HAL is a multi-disciplinary open access archive for the deposit and dissemination of sci-entific res...
International audienceLocomotion of legged robots on arbitrary terrain using multiple contacts is ye...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Electrical Engineering and Comp...
Anthropomorphic locomotion is a complex process that involves a very large number of degrees of free...
In this letter, we propose a two-stage strategy for optimal control problems of robotic mechanical s...
International audiencePlanning, adapting and executing multi-contact locomotion movements on legged ...
The fundamental objective of robotics is to enhance the productivity of humans while interacting in ...
For legged robots, generating dynamic and versatile motions is essential for interacting with comple...
Although the problem of dynamic locomotion in very rough terrain is crit-ical to the advancement of ...
Incremental progress in humanoid robot locomotion over the years has achieved essential capabilities...
International audienceThe essence of humanoid robots is their ability to reproduce human skills in l...
This paper presents a practical solution to the problem of multi-legged robot stability moving on un...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Electrical Engineering and Comp...
International audienceWe present a multi-contact walking pattern generator based on preview-control ...
Humanoids' abilities to navigate uneven terrain make them well-suited for disaster response efforts,...
HAL is a multi-disciplinary open access archive for the deposit and dissemination of sci-entific res...
International audienceLocomotion of legged robots on arbitrary terrain using multiple contacts is ye...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Electrical Engineering and Comp...
Anthropomorphic locomotion is a complex process that involves a very large number of degrees of free...
In this letter, we propose a two-stage strategy for optimal control problems of robotic mechanical s...
International audiencePlanning, adapting and executing multi-contact locomotion movements on legged ...