A measuring apparatus comprises an industrial robot and a sensor fastened to a movable arm of the robot. A calibration body comprises a calibration element, a carrier, and an alignment element rigidly arranged relative to the carrier. The alignment element interacts with a counter piece provided on a carrying structure. Data specifying the pose of the calibration element relative to the alignment element are encoded in an encoding zone which may be embodied as a data matrix code. The calibration body is initially aligned on the carrying structure with the aid of the alignment element and the counter piece. The sensor then approaches the encoding zone to read the data encoded therein. Subsequently, the pose of the calibration element relative to the carrying structure is determined using the previously read data. Finally, the pose of the calibration element is measured by the sensor to calibrate the measuring apparatus.

An end effector calibration assembly includes an electronic controller, a first camera assembly communicatively coupled to the electronic controller, and a second camera assembly communicatively coupled to the electronic controller. A first image capture path of the first camera assembly intersects a second image capture path of the second camera assembly. The electronic controller receives image data from the first camera assembly, receives image data from the second camera assembly, and calibrates a position of the robot end effector based on the image data received from the first camera assembly and the second camera assembly.

A calibration device is provided. The calibration device includes a frame, a first optical sensing device, a second optical sensing device and a third optical sensing device. The frame includes a bottom plate and at least four sidewalls, wherein the sidewalls have a first grating hole, a second grating hole, a third grating hole and a fourth grating hole at a first height. The bottom plate has an image recognition pattern, a first measurement point, a second measurement point and a third measurement point.

Systems, devices, articles, and methods are illustrated and described herein. A method of operation in a robotic system including a processor, a first device, and a second device involves receiving, by the processor, a training set including a first plurality of positions in a first configuration space that represents physical configurations of the first device, a second plurality of positions in a second configuration space that represents physical configurations of the second device, and information that represents pairs of positions. A representative pair includes a first representative position in the first configuration space and a second representative position in the second configuration space. The method involves creating, by the processor, from the training set, information that represents a map between a first run-time position in the first configuration space, and a second run-time position in the second configuration space, and returning, by the processor, the information that represents the map.

A teaching method includes imaging a teaching jig to acquire a captured image, detecting a position and a posture of the teaching jig based on the captured image, changing a position and a posture of a robot arm of a robot based on a result obtained by the detection to maintain a positional relation between the teaching jig and a control point of the robot arm, and acquiring the position and the posture of the robot arm as teaching information when a control device, which controls operation of the robot, acquires a teaching signal.

A manufacturing system includes: a coordinate positioning machine having a structure moveable within a working volume of the machine, a drive arrangement for moving the structure around the working volume, and a positioning arrangement for determining the position of the structure within the working volume with a first accuracy; and a metrology arrangement to which the machine is removably couplable, such that when the machine is coupled to the metrology arrangement, with the structure being moved by the drive arrangement, the metrology arrangement is able to measure the position of the structure with a second accuracy that is higher than the first accuracy.

A positioning system using a robot, capable of eliminating an error factor of the robot such as thermal expansion or backlash can be eliminated, and carrying out positioning of the robot with accuracy higher than inherent positioning accuracy of the robot. The positioning system has a robot with a movable arm, visual feature portions provided to a robot hand, and vision sensors positioned at a fixed position outside the robot and configured to capture the feature portions. The hand is configured to grip an object on which the feature portions are formed, and the vision sensors are positioned and configured to capture the respective feature portions.

The present disclosure envisages a system and method for self-calibration of an actuator. The system comprises a pressure spike sensing and control circuit, a travel limit setting circuit and a profile generation circuit. The pressure spike sensing and control circuit is configured to check and set an operating pressure of the actuator. The travel limit setting circuit is configured to check and set the travel limit of the actuator. The profile generation circuit is configured to generate the profiles of a set of parameters of the actuator.

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.

Systems and methods for verification and calibration of robotic instruments are provided. A robotic system may include an instrument carriage to receive an elongate device, and the instrument carriage may comprise a set of drive sensors. The system may also include a tracking system configured to receive an indication that the elongate device is installed on the instrument carriage, operate a set of actuators to articulate a distal portion of the elongate device, and generate a set of drive sensor data from the set of drive sensors. The tracking system may also be configured to generate a set of articulation sensor data from a shape sensor of the elongate device, compare the set of drive sensor data to the set of articulation sensor data to generate a test profile, and determine whether the test profile corresponds to a reference profile. Corrective action may be determined.