A method for calibrating a touchscreen panel and the system, the industrial robot and the touchscreen panel using the same. The method including the steps of: (a) defining at least one area of the touchscreen with predetermined accuracy for position measuring; (b) recording a plurality of kinematic parameters of the industrial robot on a plurality of first touch points on the at least one area of the touchscreen; (c) recording a plurality of first position values on the plurality of first touch points on the at least one area of the touchscreen; (d) determining a first calibration data for the kinematic model of the industrial robot using the kinematic parameters and using the first position values; (e) computationally correcting errors of the kinematic model of the industrial robot using the first calibration data; (f) recording a plurality of second position values on a plurality of second touch points on the at least one area with at least a portion of its border extending outwards; (g) determining a second calibration data for the touchscreen using the kinematic parameters and using the second position values; (h) computationally correcting errors of position measurement of the touchscreen using the second calibration data; and iteratively repeating the steps (b) through (h) for different postures of the industrial robot until the iteration step no longer results in significant improvement of the error correction of the kinematic model of the industrial robot.

Disclosed are systems and methods to provide a method for calibrating a touchscreen coordinate system of a touchscreen with an industrial robot coordinate system of an industrial robot for industrial robot commissioning and industrial robot system and control system using the same. In one form the systems and methods include attaching an end effector to the industrial robot; (a) moving the industrial robot in a compliant way until a stylus of the end effector touches a point on the touchscreen; (b) recording a position of the stylus of the end effector in the industrial robot coordinate system when it touches the point of the touchscreen; (c) recording a position of the touch point on the touchscreen in the touchscreen coordinate system; and calculating a relation between the industrial robot coordinate system and the touchscreen coordinate system based on the at least three positions of the end effector stylus and the at least three positions of the touch points.

Example systems and methods are disclosed for determining work offset data for a robot in a work environment. A robot operating in a work environment may receive an indication to determine a work offset. The work offset may describe the location and angular orientation of a working plane of the work environment relative to a base plane of the robot. In response to the indication, the robot may identify the working plane. The robot may be controlled to contact one or more points of the working plane. The robot may determine respective point locations of the contacted points relative to the base plane based on the respective positions of the robot at respective times of contact. The robot may determine the location and angular orientation of the working plane relative to the base plane based on the determined respective point locations of the contacted points.

Systems and methods are disclosed for determining work offset data for a robot in a work environment. In an embodiment, a robot operating in a work environment receives an indication to determine a work offset. The work offset describes the location and angular orientation of a working plane of the work environment relative to a base plane of the robot. In response to the indication, the robot identifies the working plane. The robot is controlled to contact one or more points of the working plane. The robot determines respective point locations of the contacted points relative to the base plane based on the respective positions of the robot at respective times of contact. The robot determines the location and angular orientation of the working plane relative to the base plane based on the determined respective point locations of the contacted points.

Systems, devices, and methods for time calibration. The method can include, in responses to receiving sensing data which indicates a deviation of a tool from an object to be operated by a robot with the tool, triggering the robot to perform a plurality of transformations. Each transformation causing the tool to contact the object at a reference position; determining joint positions of a joint of the robot holding the tool or the object after the plurality of transformations; and determining a position relationship between the tool and the robot at least partially based on the joint positions and the reference position.

Example systems and methods are disclosed for determining work offset data for a robot in a work environment. A robot operating in a work environment may receive an indication to determine a work offset. The work offset may describe the location and angular orientation of a working plane of the work environment relative to a base plane of the robot. In response to the indication, the robot may identify the working plane. The robot may be controlled to contact one or more points of the working plane. The robot may determine respective point locations of the contacted points relative to the base plane based on the respective positions of the robot at respective times of contact. The robot may determine the location and angular orientation of the working plane relative to the base plane based on the determined respective point locations of the contacted points.