A robot control device includes the following: a main control unit; a servo control unit, which receives a position command θc from the main control unit; and a bending correction block (24), which corrects the bending of the reduction gear connected to the servo motor. The bending correction block (24) includes the following: a first position-correction-value calculation means (63), which finds a first position-command correction value θsgc based on the position command θc; and a second position-command-correction-value calculation means (64), which finds a second position-command correction value θskc based on the interference torque τa. The servo control unit drives the servo motor based on a new position command obtained by adding the first position-command correction value θsgc and the second position-command correction value θskc to the position command θc.

Methods and robot, where payload information of a payload attached to a robot tool flange of a robot arm are obtained by arranging the robot tool flange in a plurality of different orientations in relation to gravity; obtaining the force and the torque provided to the robot tool flange by gravity acting on the payload using a force torque sensor arranged at the robot tool flange; obtaining the mass of the payload based on the obtained forces obtained at at least two of the different orientations. The dependent claims describe possible embodiments of the robot and methods according to the present invention.

A large manipulator including an extendable folding boom. The extendable boom includes a turntable that is rotatable about a vertical axis and boom segments pivotable at folding joints about folding axes in relation to an adjacent boom segment or the turntable via respective drive assemblies. The extendable boom further includes rotary angle sensors configured to detect folding angles between adjacent boom segments or between one of the boom segments and the adjacent turntable. The extendable boom further includes an inclination sensor arranged at a last of the boom segments forming a boom tip and a computing unit configured to establish an elastic deformation of the extendable folding boom based on the detected folding angles and the inclination of the last boom segment.

A robot control device includes the following: a main control unit; a servo control unit, which receives a position command c from the main control unit; and a bending correction block (24), which corrects the bending of the reduction gear connected to the servo motor. The bending correction block (24) includes the following: a first position-correction-value calculation means (63), which finds a first position-command correction value sgc based on the position command c; and a second position-command-correction-value calculation means (64), which finds a second position-command correction value skc based on the interference torque a. The servo control unit drives the servo motor based on a new position command obtained by adding the first position-command correction value sgc and the second position-command correction value skc to the position command c.

The invention relates an apparatus for analysing movement of an arrangement made of a plurality of bodies assigned to a platform, of which at least one is provided with a drive, in particular of the hexapod type or of the articulated arm type, having means for vibration analysis and/or force analysis. According to the invention, the apparatus has in a modular construction a vibration analysis module for analytically determining natural vibration modes of the bodies and/or of the platform in respect of at least one of the following variables: frequency, centre of rotation of the torsional component of the vibrations, axis of rotation of torsional vibration, displacement vector of a Cartesian vibration, amplitude ratio of the vibrations in relation to one another, and/or a force analysis module for analytically determining the acceleration forces and/or weights and/or torques, occurring on a predetermined trajectory, in respect of the bodies and/or the platform.

A large manipulator including an extendable folding boom. The extendable boom includes a turntable that is rotatable about a vertical axis and boom segments pivotable at folding joints about folding axes in relation to an adjacent boom segment or the turntable via respective drive assemblies. The extendable boom further includes rotary angle sensors configured to detect folding angles between adjacent boom segments or between one of the boom segments and the adjacent turntable. The extendable boom further includes an inclination sensor arranged at a last of the boom segments forming a boom tip and a computing unit configured to establish an elastic deformation of the extendable folding boom based on the detected folding angles and the inclination of the last boom segment.

According to an embodiment, a manipulator includes the following elements. The first joint has a rotation axis in a first direction crossing a gravity direction. The second joint has a rotation axis in a second direction crossing the first direction. The first arm and the second arm are coupled with the second joint along a third direction crossing the second direction. The variable center-of-gravity unit coupled with the first arm. The controller controls the variable center-of-gravity unit to perform an operation for moving the first weight of the variable center-of-gravity unit in a direction crossing the rotation axis of the first joint and/or an operation for moving the second weight of the variable center-of-gravity unit in a direction crossing the rotation axis of the second joint.

According to an embodiment, a manipulator includes the following elements. The first joint has a rotation axis in a first direction crossing a gravity direction. The second joint has a rotation axis in a second direction crossing the first direction. The first arm and the second arm are coupled with the second joint along a third direction crossing the second direction. The variable center-of-gravity unit coupled with the first arm. The controller controls the variable center-of-gravity unit to perform an operation for moving the first weight of the variable center-of-gravity unit in a direction crossing the rotation axis of the first joint and/or an operation for moving the second weight of the variable center-of-gravity unit in a direction crossing the rotation axis of the second joint.