Niels Dehio scite author profile

We propose a method for dual-arm manipulation of rigid objects, subject to external disturbance. The problem is formulated as a Cartesian impedance controller within a projected inverse dynamics framework. We use the constrained component of the controller to enforce contact and the unconstrained controller to accomplish the task with a desired 6-DOF impedance behaviour. Furthermore, the proposed method optimises the torque required to maintain contact, subject to unknown disturbances, and can do so without direct measurement of external force. The techniques are evaluated on a single-arm wiping a table and a dual-arm platform manipulating a rigid object of unknown mass and with human interaction. [1]

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On Inverse Inertia Matrix and Contact-Force Model for Robotic Manipulators at Normal Impacts

Wang

Dehio

Kheddar

2022

IEEE Robot. Autom. Lett.

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Multiple task optimization with a mixture of controllers for motion generation

Dehio

Reinhart

Steil

2015

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Modeling and Control of Multi-Arm and Multi-Leg Robots: Compensating for Object Dynamics During Grasping

Dehio

Smith

Wigand

et al. 2018

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We consider a virtual manipulator in grasping scenarios which allows us to capture the effect of the object dynamics. This modeling approach turns a multi-arm robot into an underactuated system. We observe that controlling floatingbase multi-leg robots is fundamentally similar. The Projected Inverse Dynamics Control approach is employed for decoupling contact consistent motion generation and controlling contact wrenches. The proposed framework for underactuated robots has been evaluated on an enormous robot hand composed of four KUKA LWR IV+ representing fingers cooperatively manipulating a 9kg box with total 28 actuated DOF and six virtual DOF representing the object as additional free-floating robot link. Finally, we validate the same approach on ANYmal, a floating-base quadruped with 12 actuated DOF. Experiments are performed both in simulation and real world.

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Niels Dehio

A Projected Inverse Dynamics Approach for Multi-Arm Cartesian Impedance Control

On Inverse Inertia Matrix and Contact-Force Model for Robotic Manipulators at Normal Impacts

Multiple task optimization with a mixture of controllers for motion generation

Modeling and Control of Multi-Arm and Multi-Leg Robots: Compensating for Object Dynamics During Grasping

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