This work investigates the way humans plan their paths in a goal-directed motion, assuming that a person acts as an optimal controller that plans the path minimizing a certain (unknown) cost function. Taking this viewpoint, the problem can be formulated as an inverse optimal control one, i.e., starting from control and state trajectories one wants to figure out the cost function used by a person while planning the path. The so-obtained model can be used to support the design of safe human-robot interaction systems, as well as to plan human-like paths for humanoid robots. To test the envisaged ideas, a set of walking paths of different volunteers were recorded using a motion capture facility. The collected data were used to compare two solut...
Abstract — In recent papers it has been suggested that human locomotion may be modeled as an inverse...
Abstract—In this paper, we present a method for learning the reward function for humanoid locomotion...
Abstract—This paper presents a human-inspired control approach to bipedal robotic walking: utilizing...
This work investigates the way humans plan their paths in a goal-directed motion, assuming that a pe...
This work investigates the way humans plan their paths in a goal-directed motion. The person can be ...
International audienceCobotic applications require a good knowledge of human behaviour in order to b...
In this paper we explore the underlying principles of natural locomotion path generation of human be...
Abstract—In this paper, we investigate different possible strate-gies underlying the formation of hu...
This paper explores the use of optimal control for quasi-static bipedal walking trajectory synthesis...
International audienceIn order to smoothly perform interactions between a humanoid robot and a human...
In recent papers it has been suggested that human locomotion may be modeled as an inverse optimal co...
Human-robot collaboration can be improved if the motions of the robot are more legible and predictab...
International audienceIn order to fluidly perform complex tasks in collaboration with a human being,...
Abstract — This paper presents a method to determine out-puts associated with human walking data tha...
Pedestrian navigation is a complex function of human dynamics, a desired destination, and the presen...
Abstract — In recent papers it has been suggested that human locomotion may be modeled as an inverse...
Abstract—In this paper, we present a method for learning the reward function for humanoid locomotion...
Abstract—This paper presents a human-inspired control approach to bipedal robotic walking: utilizing...
This work investigates the way humans plan their paths in a goal-directed motion, assuming that a pe...
This work investigates the way humans plan their paths in a goal-directed motion. The person can be ...
International audienceCobotic applications require a good knowledge of human behaviour in order to b...
In this paper we explore the underlying principles of natural locomotion path generation of human be...
Abstract—In this paper, we investigate different possible strate-gies underlying the formation of hu...
This paper explores the use of optimal control for quasi-static bipedal walking trajectory synthesis...
International audienceIn order to smoothly perform interactions between a humanoid robot and a human...
In recent papers it has been suggested that human locomotion may be modeled as an inverse optimal co...
Human-robot collaboration can be improved if the motions of the robot are more legible and predictab...
International audienceIn order to fluidly perform complex tasks in collaboration with a human being,...
Abstract — This paper presents a method to determine out-puts associated with human walking data tha...
Pedestrian navigation is a complex function of human dynamics, a desired destination, and the presen...
Abstract — In recent papers it has been suggested that human locomotion may be modeled as an inverse...
Abstract—In this paper, we present a method for learning the reward function for humanoid locomotion...
Abstract—This paper presents a human-inspired control approach to bipedal robotic walking: utilizing...