A method for calibrating a system with a conveying apparatus and at least a first robot includes determining the positions of at least three measuring points of a first component transported by the conveying apparatus in a first transport position using the first robot. The method further includes determining the position of at least one of the measuring points in a second transport position using the first robot, or determining the positions of at least two of the measuring points of the component in a third transport position and the position of at least one other measuring point in the third transport position or at least one of these measuring points in a fourth transport position using at least one second robot.

This method is for calibrating a coordinate system of an image capture device and a coordinate system of a robot arm in a robot system that includes a display device, the image capture device, and the robot arm to which one of the display device and the image capture device is fixed, the robot arm having a drive shaft. The method includes: acquiring first captured image data based on first image data; acquiring second captured image data based on second image data different from the first image data; and calibrating the coordinate system of the image capture device and the coordinate system of the robot arm, using the first captured image data and the second captured image data.

There is provided for a calibration method for an operation apparatus. The operation apparatus comprises a first moving body unit capable of pivoting about a horizontally extending axis, a first driving unit configured to drive the first moving body unit, and a first detection unit configured to detect a pivot position of the first moving body unit. The method comprises aligning the first moving body unit to one reference position selected from a plurality of predetermined reference positions, determining the reference position by comparing a driving parameter value of the first driving unit at the one reference position with determination parameter values respectively preset for the plurality of reference positions, and registering, as reference position information for calculating the pivot position, position information of the one reference position determined in the determining and detection value information of the first detection unit.

A robot includes a robot control unit configured to control an operation of a robot, wherein the robot control unit is configured to set a coordinate system of the robot installed on a reference flat surface using measurement results of at least position coordinates in a vertical direction of three or more measurement points on the reference flat surface on which the robot is installed and measurement results of position coordinates of a plurality of reference reflection portions provided on a base portion of the robot.

Systems and methods for calibrating sensors of a robot are disclosed. In one exemplary implementation, an environment comprising a plurality of sensor targets and a fixed position for a robot allows for faster, more accurate calibration of a robot's sensors.

In some embodiments, correcting an alignment error between an end effector of a tool associated with a slave and a master actuator associated with a master in a robotic system involves receiving at the master, master actuator orientation signals (R.sub.MCURR) representing the orientation of the master actuator relative to a master reference frame and generating end effector orientation signals (R.sub.EENEW) representing the end effector orientation relative to a slave reference frame, producing control signals based on the end effector orientation signals, receiving an enablement signal for selectively enabling the control signals to be transmitted from the master to the slave, responsive to a transition of the enablement signal from not active state to active state, computing the master-slave misalignment signals (R.sub.) as a difference between the master actuator orientation signals (R.sub.MCURR) and the end effector orientation signals (R.sub.EENEW), and adjusting the master-slave misalignment signals (R.sub.) to reduce the alignment difference.

A method for characterising the environment of a robot, the robot having a flexible arm having a plurality of joints, a datum carried by the arm, a plurality of drivers arranged to drive the joints to move and a plurality of position sensors for sensing the position of each of the joints, the method comprising: contacting the datum carried by the arm with a first datum on a second robot in the environment of the first robot, wherein the second robot has a flexible arm having a plurality of joints, and a plurality of drivers arranged to drive those joints to move; calculating in dependence on the outputs of the position sensors a distance between a reference location defined in a frame of reference local to the robot and the first datum; and controlling the drivers to reconfigure the first arm in dependence on at least the calculated distance.

Embodiments of the present disclosure provide methods for managing a robot system. In the method, orientations for links in the robot system may be obtained when the links are arranged in at least one posture, here each of the orientations indicates a direction pointed by one of the links. At least one image of an object placed in the robot system may be obtained from a vision device equipped on one of the links. Based on the orientations and the at least one image, a first mapping may be determined between a vision coordinate system of the vision device and a link coordination system of the link. Further, embodiments of present disclosure provide apparatuses, systems, and computer readable media for managing a robot system. The vision device may be calibrated by the first mapping and may be used to manage operations of the robot system.

A robot system includes a robot, a robot work environment in which the robot works, and a robot controller including circuitry that stores position information indicating a position of each of measured robot postures in the robot work environment, obtains a measured position of each of the measured robot postures based on a detection result obtained by a sensor, and corrects a movement position of the robot based on the measured position.

A method of operating a manipulation system of the type having a movable arm with a proximal end connected to a base and a distal end that is movable relative to the base and is coupled to an end-effector. The method comprises moving the distal end of the movable arm towards a target object and into contact with a stabilization object proximate to the target object, maintaining contact between the distal end of the movable arm and the stabilization object while operating the end-effector to perform a desired operation at the target object, and upon completing the desired operation at the target object, disengaging the distal end of the movable arm from contact with the stabilization object.