International audienceLegged robots are typically in rigid contact with the environment at multiple locations, which add a degree of complexity to their control. We present a method to control the motion and a subset of the contact forces of a floating-base robot. We derive a new formulation of the lexicographic optimization problem typically arising in multi-task motion/force control frameworks. The structure of the constraints of the problem (i.e. the dynamics of the robot) allows us to find a sparse analytical solution. This leads to an equivalent optimization with reduced computational complexity, comparable to inverse-dynamics based approaches. At the same time, our method preserves the flexibility of optimization based control framewo...
International audienceWe propose a formal analysis with some theoretical properties of weight-priori...
This paper presents practical enhancements of the operational space formulation (OSF) to exploit ine...
The stiffness ellipsoid, i.e. the locus of task-space forces obtained corresponding to a deformation...
International audienceLegged robots are typically in rigid contact with the environment at multiple ...
Pre-print of paper presented at Intelligent Robots and Systems (IROS 2014), IEEE International Confe...
International audienceIn this work we present a novel method to address the balancing problem for to...
2018-07-26In this work, we explore computationally lightweight optimization-based methods for planni...
International audienceThe most widely-used technique to generate wholebody motions on a humanoid rob...
This paper addresses the problem of constrained motion for a manipulator performing a task while in ...
This paper presents a dynamic locomotion generation for a one-legged floating-base robot. Reference ...
This work presents a new control approach to multi-contact balancing for torque-controlled humanoid ...
Abstract—The possibility of controlling humanoid robots in free-space opens new fields of applicatio...
International audienceHumanoid robots propel themselves and perform tasks by interacting with their ...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Electrical Engineering and Comp...
An approach is proposed to simultaneously control the contact forces exerted on a constraint surface...
International audienceWe propose a formal analysis with some theoretical properties of weight-priori...
This paper presents practical enhancements of the operational space formulation (OSF) to exploit ine...
The stiffness ellipsoid, i.e. the locus of task-space forces obtained corresponding to a deformation...
International audienceLegged robots are typically in rigid contact with the environment at multiple ...
Pre-print of paper presented at Intelligent Robots and Systems (IROS 2014), IEEE International Confe...
International audienceIn this work we present a novel method to address the balancing problem for to...
2018-07-26In this work, we explore computationally lightweight optimization-based methods for planni...
International audienceThe most widely-used technique to generate wholebody motions on a humanoid rob...
This paper addresses the problem of constrained motion for a manipulator performing a task while in ...
This paper presents a dynamic locomotion generation for a one-legged floating-base robot. Reference ...
This work presents a new control approach to multi-contact balancing for torque-controlled humanoid ...
Abstract—The possibility of controlling humanoid robots in free-space opens new fields of applicatio...
International audienceHumanoid robots propel themselves and perform tasks by interacting with their ...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Electrical Engineering and Comp...
An approach is proposed to simultaneously control the contact forces exerted on a constraint surface...
International audienceWe propose a formal analysis with some theoretical properties of weight-priori...
This paper presents practical enhancements of the operational space formulation (OSF) to exploit ine...
The stiffness ellipsoid, i.e. the locus of task-space forces obtained corresponding to a deformation...