A framework for modeling and control is introduced for robotic manipulators with a number of energetically self-contained semiactive joints. The control approach consists of three steps. First, a virtual control design is conducted by any suitable means, assuming a fully-actuated system. Then, virtual control inputs are matched by a parameter modulation law. Finally, the storage dynamics are shaped using design parameters. Storage dynamics coincide with the system\u27s internal dynamics under exact virtual control matching. An internal energy balance equation and associated self-powered operation condition are given for the semiactive joints. This condition is a structural characteristic of the system and independent of the control law. Mor...
In this paper, we develop theoretical foundations for a new class of rehabilitation robot: body powe...
© 2021 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
This research focuses on the energy-oriented control of robotic systems using an ultracapacitor as t...
A framework for modeling and control is introduced for robotic manipulators with a number of energet...
Abstract: A framework for modeling and control is introduced for robotic manipulators with a number ...
This paper focuses on robot control problems where energy regeneration is an explicit consideration,...
We investigate the control and optimization of robots with ultracapacitor based regenerative drive s...
We design an optimal passivitybased tracking/impedance control system for a robotic manipulator with...
This paper focuses on the design, modeling and basic control of a variable stiffness actuator to be ...
This paper presents a control method based on virtual passive dynamic control that will stabilize a ...
Two regenerative motor drives, a voltage source converter and a bidirectional buck/boost converter, ...
In this work, simultaneous energy regeneration and motion control for robot manipulators with brushl...
The paper presents a new control law for elastic joint robots that allows to regulate the energy sto...
Robot arms with intrinsically elastic joints became very popular over the last years. Considerable e...
In this paper, we develop theoretical foundations for a new class of rehabilitation robot: body powe...
© 2021 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
This research focuses on the energy-oriented control of robotic systems using an ultracapacitor as t...
A framework for modeling and control is introduced for robotic manipulators with a number of energet...
Abstract: A framework for modeling and control is introduced for robotic manipulators with a number ...
This paper focuses on robot control problems where energy regeneration is an explicit consideration,...
We investigate the control and optimization of robots with ultracapacitor based regenerative drive s...
We design an optimal passivitybased tracking/impedance control system for a robotic manipulator with...
This paper focuses on the design, modeling and basic control of a variable stiffness actuator to be ...
This paper presents a control method based on virtual passive dynamic control that will stabilize a ...
Two regenerative motor drives, a voltage source converter and a bidirectional buck/boost converter, ...
In this work, simultaneous energy regeneration and motion control for robot manipulators with brushl...
The paper presents a new control law for elastic joint robots that allows to regulate the energy sto...
Robot arms with intrinsically elastic joints became very popular over the last years. Considerable e...
In this paper, we develop theoretical foundations for a new class of rehabilitation robot: body powe...
© 2021 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
This research focuses on the energy-oriented control of robotic systems using an ultracapacitor as t...