Abstract—This paper presents a control framework for humanoid robots that uses all joints simultaneously to track motion capture data and maintain balance. The controller comprises two main components: a balance controller and a tracking controller. The balance controller uses a regulator designed for a simplified humanoid model to obtain the desired input to keep balance based on the current state of the robot. The simplified model is chosen so that a regulator can be designed systematically using, for example, optimal control. An example of such controller is a linear quadratic regulator designed for an inverted pendulum model. The desired inputs are typically the center of pressure and/or torques of some representative joints. The tracki...
This paper deals with the whole body motion control problem of humanoid robots by using automatic an...
Humanoid robots are considered as complex and challenging platforms, and the state of the art in rob...
Humanoid robots in any environment are likely to experience collisions with obstacles or imbalance w...
International audienceIn this study, we endeavor to better understand the human motor control system...
Abstract — Physical humanoids often require the ability to maintain upright balance while performing...
Recently several hierarchical inverse dynamics controllers based on cascades of quadratic programs h...
Abstract — In this contribution we propose a reformulation of a momentum-based balance controller or...
Abstract—Nature has developed methods for controlling the movements of organisms with many degrees o...
Humanoid robots represent the state of the art in complex robot systems. High performance controller...
Abstract—This paper proposes an effective framework of human-humanoid robot physical interaction. It...
This thesis aims at generating human-like, whole-body humanoid motion trajectories and introducing a...
A humanoid robot is expected to experience various force disturbances during interaction with humans...
Humanoid robots have the potential to become a part of everyday life as their hardware and software ...
Abstract—This paper introduces and compares two control approaches that increase the robustness of h...
Direct transfer of human motion trajectories to humanoid robots does not result in dynamically stabl...
This paper deals with the whole body motion control problem of humanoid robots by using automatic an...
Humanoid robots are considered as complex and challenging platforms, and the state of the art in rob...
Humanoid robots in any environment are likely to experience collisions with obstacles or imbalance w...
International audienceIn this study, we endeavor to better understand the human motor control system...
Abstract — Physical humanoids often require the ability to maintain upright balance while performing...
Recently several hierarchical inverse dynamics controllers based on cascades of quadratic programs h...
Abstract — In this contribution we propose a reformulation of a momentum-based balance controller or...
Abstract—Nature has developed methods for controlling the movements of organisms with many degrees o...
Humanoid robots represent the state of the art in complex robot systems. High performance controller...
Abstract—This paper proposes an effective framework of human-humanoid robot physical interaction. It...
This thesis aims at generating human-like, whole-body humanoid motion trajectories and introducing a...
A humanoid robot is expected to experience various force disturbances during interaction with humans...
Humanoid robots have the potential to become a part of everyday life as their hardware and software ...
Abstract—This paper introduces and compares two control approaches that increase the robustness of h...
Direct transfer of human motion trajectories to humanoid robots does not result in dynamically stabl...
This paper deals with the whole body motion control problem of humanoid robots by using automatic an...
Humanoid robots are considered as complex and challenging platforms, and the state of the art in rob...
Humanoid robots in any environment are likely to experience collisions with obstacles or imbalance w...