Transferring human stiffness regulation strategies to robots enables them to effectively and efficiently acquire adaptive impedance control policies to deal with uncertainties during the accomplishment of physical contact tasks in an unstructured environment. In this work, we develop such a physical human-robot interaction (pHRI) system which allows robots to learn variable impedance skills from human demonstrations. Specifically, the biological signals, i.e., surface electromyography (sEMG) are utilized for the extraction of human arm stiffness features during the task demonstration. The estimated human arm stiffness is then mapped into a robot impedance controller. The dynamics of both movement and stiffness are simultaneously modeled by ...
It is one of the great challenges for a robot to learn compliant movements in interaction tasks. The...
In this work, we propose a practical approach to estimate human joint stiffness during tooling tasks...
Humans use their limbs to perform various movements to interact with an external environment. Thanks...
In recent years, robots have been successfully applied to automate repetitive, structured and non-co...
Learning from Demonstration in robotics has proved its efficiency in robot skill learning. The gener...
© 2022 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
© 2016 Peidong Liang et al. We have developed a new discrete-time algorithm of stiffness extraction ...
Learning from Demonstration in robotics has proved its efficiency in robot skill learning. The gener...
In the last decades robots are expected to be of increasing intelligence to deal with a large range ...
This thesis introduces novel thinking and techniques to the control of robotic manipulation. In part...
In the last years, realistic applications have brought robots to complex environments such as museum...
Human Robot Interaction has become a key point in the development of new robotic interfaces and cont...
International audienceThis paper presents an adaptive impedance control architecture for robotic tel...
To approach robustness and optimal performance, biological musculo-skeletal systems can adapt their...
© 2013 IEEE. Learning a task such as pushing something, where the constraints of both position and f...
It is one of the great challenges for a robot to learn compliant movements in interaction tasks. The...
In this work, we propose a practical approach to estimate human joint stiffness during tooling tasks...
Humans use their limbs to perform various movements to interact with an external environment. Thanks...
In recent years, robots have been successfully applied to automate repetitive, structured and non-co...
Learning from Demonstration in robotics has proved its efficiency in robot skill learning. The gener...
© 2022 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
© 2016 Peidong Liang et al. We have developed a new discrete-time algorithm of stiffness extraction ...
Learning from Demonstration in robotics has proved its efficiency in robot skill learning. The gener...
In the last decades robots are expected to be of increasing intelligence to deal with a large range ...
This thesis introduces novel thinking and techniques to the control of robotic manipulation. In part...
In the last years, realistic applications have brought robots to complex environments such as museum...
Human Robot Interaction has become a key point in the development of new robotic interfaces and cont...
International audienceThis paper presents an adaptive impedance control architecture for robotic tel...
To approach robustness and optimal performance, biological musculo-skeletal systems can adapt their...
© 2013 IEEE. Learning a task such as pushing something, where the constraints of both position and f...
It is one of the great challenges for a robot to learn compliant movements in interaction tasks. The...
In this work, we propose a practical approach to estimate human joint stiffness during tooling tasks...
Humans use their limbs to perform various movements to interact with an external environment. Thanks...