Guanine tautomerism revealed by UV–UV and IR–UV hole burning spectroscopy

High risk of a collision between rotor blades and the obstacles in a complex environment imposes restrictions on the aerial manipulators. To solve this issue, a novel system cable-Suspended Aerial Manipulator (SAM) is presented in this paper. Instead of attaching a robotic manipulator directly to an aerial carrier, it is mounted on an active platform which is suspended on the carrier by means of a cable. As a result, higher safety can be achieved because the aerial carrier can keep a distance from the obstacles. For self-stabilization, the SAM is equipped with two actuation systems: winches and propulsion units. This paper presents an overview of the SAM including the concept behind, hardware realization, control strategy, and the first experimental results.

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Visual-Inertial Telepresence for Aerial Manipulation

Lee

Balachandran

Sarkisov

et al. 2020

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DroneGear: A Novel Robotic Landing Gear With Embedded Optical Torque Sensors for Safe Multicopter Landing on an Uneven Surface

Sarkisov

Yashin

Tsykunov

et al. 2018

IEEE Robot. Autom. Lett.

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Optimal Oscillation Damping Control of cable-Suspended Aerial Manipulator with a Single IMU Sensor

Sarkisov

Kim

Coelho

et al. 2020

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During operation, aerial manipulation systems are affected by various disturbances. Among them is a gravitational torque caused by the weight of the robotic arm. Common propeller-based actuation is ineffective against such disturbances because of possible overheating and high power consumption. To overcome this issue, in this paper we propose a winchbased actuation for the crane-stationed cable-suspended aerial manipulator. Three winch-controlled suspension rigging cables produce a desired cable tension distribution to generate a wrench that reduces the effect of gravitational torque. In order to coordinate the robotic arm and the winch-based actuation, a model-based hierarchical whole-body controller is adapted. It resolves two tasks: keeping the robotic arm end-effector at the desired pose and shifting the system center of mass in the location with zero gravitational torque. The performance of the introduced actuation system as well as control strategy is validated through experimental studies.

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Whole-Body Teleoperation and Shared Control of Redundant Robots with Applications to Aerial Manipulation

Coelho

Sarkisov

et al. 2021

J Intell Robot Syst

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This paper introduces a passivity-based control framework for multi-task time-delayed bilateral teleoperation and shared control of kinematically-redundant robots. The proposed method can be seen as extension of state-of-the art hierarchical whole-body control as it allows for some of the tasks to be commanded by a remotely-located human operator through a haptic device while the others are autonomously performed. The operator is able to switch among tasks at any time without compromising the stability of the system. To enforce the passivity of the communication channel as well as to dissipate the energy generated by the null-space projectors used to enforce the hierarchy among the tasks, the Time-Domain Passivity Approach (TDPA) is applied. The efficacy of the approach is demonstrated through its application to the DLR Suspended Aerial Manipulator (SAM) in a real telemanipulation scenario with variable time delay, jitter, and package loss.

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Yu. S. Sarkisov

Development of SAM: cable-Suspended Aerial Manipulator

Visual-Inertial Telepresence for Aerial Manipulation

DroneGear: A Novel Robotic Landing Gear With Embedded Optical Torque Sensors for Safe Multicopter Landing on an Uneven Surface

Optimal Oscillation Damping Control of cable-Suspended Aerial Manipulator with a Single IMU Sensor

Whole-Body Teleoperation and Shared Control of Redundant Robots with Applications to Aerial Manipulation

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