Tendon controlled robots with nonlinear mechanical tendon stiffness are becoming more and more popular. With the appropriate actuation, the joint position and the stiffness between motor and link side can be prescribed at the same time. In this paper, the modeling of tendon-driven elastic systems with nonlinear couplings is recapitulated. Based on the Immersion and Invariance (I&I) framework a control law is developed that takes trajectories of the desired joint position and the pretension as input. The contribution of this paper are the application of the I&I framework to tendon-controlled systems with variable stiffness which requires to consider the internal degrees of freedom to realize the pretension, respectively the mechanical jo...
In this paper we evaluate the potential of Variable Stiffness Actuation to utilize its inherent joi...
Conventionally, tendon-driven manipulators implement some force control scheme based on tension feed...
Annunziata S, Schneider A. Physiologically based control laws featuring antagonistic muscle co-activ...
Abstract — The current discussion on physical human robot interaction and the related safety aspects...
We propose an impedance controller for articulated soft robots implemented by bidirectional antagoni...
Traditionally, most of the nonlinear control techniques for elastic robotic systems focused on achie...
This paper addresses stiffness modulation and antagonistic actuation in lightweight tendon-driven bi...
In this paper, the dynamic model of a robot with antagonistic actuated joints is presented, and the ...
Since safe human-robot interaction is naturally linked to compliance in these robots, this requirem...
Tendon driven mechanisms have been considered in robotic design for several decades. They provide li...
Abstract: One of the major limitations of object manipulation with a robotic hand is the fragility o...
Physical compliance can be considered one of the key technical properties a robot should exhibit to ...
The variable stiffness actuation concept is considered to provide a human-friendly robot technology....
While dexterous robotic manipulation research has made significant advancements in the last two deca...
This article addresses the problem of simultaneous and robust closed-loop control of joint stiffness...
In this paper we evaluate the potential of Variable Stiffness Actuation to utilize its inherent joi...
Conventionally, tendon-driven manipulators implement some force control scheme based on tension feed...
Annunziata S, Schneider A. Physiologically based control laws featuring antagonistic muscle co-activ...
Abstract — The current discussion on physical human robot interaction and the related safety aspects...
We propose an impedance controller for articulated soft robots implemented by bidirectional antagoni...
Traditionally, most of the nonlinear control techniques for elastic robotic systems focused on achie...
This paper addresses stiffness modulation and antagonistic actuation in lightweight tendon-driven bi...
In this paper, the dynamic model of a robot with antagonistic actuated joints is presented, and the ...
Since safe human-robot interaction is naturally linked to compliance in these robots, this requirem...
Tendon driven mechanisms have been considered in robotic design for several decades. They provide li...
Abstract: One of the major limitations of object manipulation with a robotic hand is the fragility o...
Physical compliance can be considered one of the key technical properties a robot should exhibit to ...
The variable stiffness actuation concept is considered to provide a human-friendly robot technology....
While dexterous robotic manipulation research has made significant advancements in the last two deca...
This article addresses the problem of simultaneous and robust closed-loop control of joint stiffness...
In this paper we evaluate the potential of Variable Stiffness Actuation to utilize its inherent joi...
Conventionally, tendon-driven manipulators implement some force control scheme based on tension feed...
Annunziata S, Schneider A. Physiologically based control laws featuring antagonistic muscle co-activ...