A control strategy for operating unknown constrained mechanisms

Abstract: This work aims at the development of a versatile control strategy for operating unknown mechanically constrained devices such as drawers or doors. Few assumptions on the device's shape as well as the utilized hardware are required. Our approach is based on an on-line estimation of the constraint manifold which serves as a reference input for an admittance-type controller providing the compliance required. The direction estimation is obtained from the velocity signal in task space. An on-line adaptation of the … Show more

“…We employ the same technique as in [16], which will be recapitulated in section III-A before the SPG strategy for a joint-level IFC is presented in section III-B.…”

“…In [16], we proposed an interaction controller for an admittance controlled mobile manipulator combined with a constraint estimator, based on filtering of the end effector velocity. The present work is a generalization of this approach to a wider class of robots.…”

“…The present work is a generalization of this approach to a wider class of robots. While the strategy developed in [16] was specific to admittance controlled robots, we formulate a more general method, which should be realizable on any IFC manipulator. Simple IFCs, like the PD+ controller, provide compliance at joint level, hence the Cartesian positioning error is not aligned with the applied end effector forces.…”

“…However, the application for Cartesian compliance is straight forward and its effectiveness has already been demonstrated in [16]. We do not assume detailed knowledge neither about the constraints, nor the required interaction forces.…”

“…To our best knowledge, robotic implementations utilizing IFC in this context, was first used in [10] and our own work presented in [16]. However, interaction forces were not explicitly considered in neither of these earlier works.…”

A set-point-generator for indirect-force-controlled manipulators operating unknown constrained mechanisms

“…We employ the same technique as in [16], which will be recapitulated in section III-A before the SPG strategy for a joint-level IFC is presented in section III-B.…”

“…In [16], we proposed an interaction controller for an admittance controlled mobile manipulator combined with a constraint estimator, based on filtering of the end effector velocity. The present work is a generalization of this approach to a wider class of robots.…”

“…The present work is a generalization of this approach to a wider class of robots. While the strategy developed in [16] was specific to admittance controlled robots, we formulate a more general method, which should be realizable on any IFC manipulator. Simple IFCs, like the PD+ controller, provide compliance at joint level, hence the Cartesian positioning error is not aligned with the applied end effector forces.…”

“…However, the application for Cartesian compliance is straight forward and its effectiveness has already been demonstrated in [16]. We do not assume detailed knowledge neither about the constraints, nor the required interaction forces.…”

“…To our best knowledge, robotic implementations utilizing IFC in this context, was first used in [10] and our own work presented in [16]. However, interaction forces were not explicitly considered in neither of these earlier works.…”

A set-point-generator for indirect-force-controlled manipulators operating unknown constrained mechanisms

Robust and adaptive door operation with a mobile robot

Multiple mode control of a compact wrist with application to door opening