According to the present invention, a plurality of actual spots where normal directions of welding surfaces are parallel to each other and arranged successively, are set as a spot group. Then, when the actual spots included in the spot group are collectively moved in the same direction by the same distance, a search is conducted of candidates for the directions and the distances that cause the actual spots having been moved to approach welding points. Further, optimum direction and distance are selected from among the candidates for the directions and distances, and a plurality of teaching points corresponding to the plurality of actual spots included in the spot group are corrected by using the selected direction and distance.

A method including, based at least partially upon a command transmission to at least one motor of a robot, estimating deflection for at least one member of the robot during movement of the robot; based at least partially upon the estimated deflection, determining calculated end effector coordinates for an end effector of the robot; and based at least partially upon the calculated end effector coordinates, adjusting movement of the robot for placing a substrate, located on the robot, at a desired location.

An apparatus for controlling and regulating a movement of a system includes a load calculating device calculating continuously during the movement of the system a respective force vector for each of the individual elements as a function of predetermined reference coordinates and a torque calculating device calculating continuously during the movement at least one compensating variable, wherein the compensating variable compensates the force vectors as a function of the reference coordinates and the force vectors. The apparatus for controlling and regulating has a control unit controlling continuously during the movement a force-producing variable for the at least one drive as a function of the reference and the at least one compensating variable.

A teach pendant includes an input unit and allowing teaching of operation of a robot by an input to the input unit, the teach pendant further includes a measurement reference surface which comes into surface contact with a measured surface of the robot, a tilt sensor whose position is fixed with respect to the measurement reference surface, and an output means which outputs a detection value of the tilt sensor to a control device of the robot in a state where the measurement reference surface is in surface contact with the measured surface and when a predetermined input operation is performed on the input unit or a contact detection sensor for detecting surface contact between the measurement reference surface and the measured surface detects the surface contact.

A measured mark is arranged on a link of an articulated robot. A camera for measuring a position of the measured mark is arranged at a position distant from the articulated robot. A control apparatus of the articulated robot changes posture of the articulated robot, measures positions of the measured mark respectively before and after a change of the posture by the camera, and calculates an actual deflection amount of the link based on a movement amount between the position of the measured mark measured before the change of the posture and the position of the measured mark measured after the change of the posture.

The invention relates to a control method for a robot (1) having a plurality of movable robot axes (2, 4, 6), in particular for a painting robot (1) or a manipulating robot, comprising the following steps: (a) predetermining a robot path by means of a plurality of path points through which a reference point of the robot (1) is intended to travel; (b) controlling drive motors of the individual robot axes (2, 4, 6) according to the predetermined robot path, such that the reference point of the robot (1) travels through the predetermined robot path; (c) precalculating the mechanical loading (My1, Mx1, Fx1, Fy1, Fz1, Fx2, Fy2, Fz2, Mx2, My2, Mz2) that occurs within at least one of the robot axes (2, 4, 6) between two joints when travelling through the robot path ahead; and also (d) adjusting the control of the drive motors of the robot axes (2, 4, 6) on the basis of the precalculated mechanical loading (My1, Mx1, Fx1, Fy1, Fz1, Fx2, Fy2, Fz2, Mx2, My2, Mz2), such that a mechanical overload is avoided.

A measured mark is arranged on a link of an articulated robot. A camera for measuring a position of the measured mark is arranged at a position distant from the articulated robot. A control apparatus of the articulated robot changes posture of the articulated robot, measures positions of the measured mark respectively before and after a change of the posture by the camera, and calculates an actual deflection amount of the link based on a movement amount between the position of the measured mark measured before the change of the posture and the position of the measured mark measured after the change of the posture.

A robot control apparatus controls a motor for driving a robot fixedly installed on a support body. The robot control apparatus is provided with a deflection estimating unit for estimating, when the robot is assumed to reach a target position and posture, a deflection arising in the support body due to the influence of gravity acting on the robot, a movement amount calculating unit for calculating the amount of movement of the motor which causes the robot to reach the target position and posture, based on the deflection of the support body, which is estimated by the deflection estimating unit, and a drive unit for driving the motor based on the amount of movement calculated by the movement amount calculating unit.

A system and method for reducing mechanical oscillations in a multi-axis control system provides a first command for a dynamic notch filter at a first update rate to multiple motor drives. Each motor drive is operatively connected to a motor for an axis in the multi-axis control system. Each motor drive receives a second command for desired operation of the motor at a second update rate. Operation of the dynamic notch filter in each motor drive is changed as a function of the first command at the first update rate, and each motor drive generates a desired output voltage for desired operation of the motor at a third update rate. The third update rate is faster than the second update rate, the second command is passed through the dynamic notch filter to generate a filtered command, and the desired output voltage is generated as a function of the filtered command.

A system and method for reducing mechanical oscillations in a multi-axis control system provides a first command for a dynamic notch filter at a first update rate to at least one motor drive. Each motor drive is connected to a motor for an axis in the multi-axis control system. Each motor drive receives a second command for desired operation of the motor at a second update rate. Operation of the dynamic notch filter in each motor drive is changed as a function of the first command at the first update rate, and each motor drive generates a desired output voltage for operation of the motor at a third update rate. The third update rate is faster than the second update rate, the second command is passed through the dynamic notch filter to generate a filtered command, and the desired output voltage is generated as a function of the filtered command.