The disclosure relates to a method for operating a robot, a data memory with a corresponding program code, the corresponding robot, and a corresponding robot system. Different coordinate system and their relationships to one another are used to position a tool in a target pose. A stationary reference coordinate system originating at a robot foot of the robot and a target coordinate system originating at the tool are specified. Herein, a z-axis of the target coordinate system corresponds to a specified axis of the tool. The orientations of an x-axis and a y-axis of the target coordinate system are calculated by a first cross product of the orientation of the specified axis and a direction vector, that is not parallel thereto, of coordinate axis of the reference coordinate system and by a second cross product of a result of the first cross product and the orientation of the specified axis.

A control apparatus includes an operation unit that teaches the robot a position, a posture changing instruction unit that instructs a position change when the robot passes through a singularity or its vicinity, a singularity passing motion request unit that instructs the robot to change its posture, a robot drive information request unit that acquires robot drive information, and a robot G-code generation unit that inserts a G-code from the robot drive information into a program. A robot includes a drive control unit that drives the robot, a singularity determination unit that determines passage through the singularity or its vicinity, a singularity passing pattern generation unit that generates a motion plan for passage through the singularity or its vicinity based on the changed posture, and a robot drive information output unit that transmits the robot drive information to the control apparatus.

A control apparatus includes an operation unit that teaches the robot a position, a posture changing instruction unit that instructs a position change when the robot passes through a singularity or its vicinity, a singularity passing motion request unit that instructs the robot to change its posture, a robot drive information request unit that acquires robot drive information, and a robot G-code generation unit that inserts a G-code from the robot drive information into a program. A robot includes a drive control unit that drives the robot, a singularity determination unit that determines passage through the singularity or its vicinity, a singularity passing pattern generation unit that generates a motion plan for passage through the singularity or its vicinity based on the changed posture, and a robot drive information output unit that transmits the robot drive information to the control apparatus.

A system and method are provided for controlling a robot for automatic positioning of a tool in a predetermined target pose. A six dimensional pose of a robot flange corresponding to the target pose is determined. An expanded kinematics of the robot is created by augmenting it with a virtual joint arranged in the tool. The virtual joint makes possible a restriction-free virtual rotation about a predetermined axis of the tool. From the six dimensional pose of the robot flange and the expanded kinematics, a path is determined by an automatic path planning module, in accordance with which the six dimensional pose of the robot flange may be moved to from an initial pose of the robot. Conflicts with a maximum physical scope of movement of the robot occurring during this process are resolved by a rotation of the virtual joint.

The disclosure relates to a method for operating a robot, a data memory with a corresponding program code, the corresponding robot, and a corresponding robot system. Different coordinate system and their relationships to one another are used to position a tool in a target pose. A stationary reference coordinate system originating at a robot foot of the robot and a target coordinate system originating at the tool are specified. Herein, a z-axis of the target coordinate system corresponds to a specified axis of the tool. The orientations of an x-axis and a y-axis of the target coordinate system are calculated by a first cross product of the orientation of the specified axis and a direction vector, that is not parallel thereto, of coordinate axis of the reference coordinate system and by a second cross product of a result of the first cross product and the orientation of the specified axis.