A robot system is provided which can suitably perform robot movement correction. The robot system is provided with: a visual sensor which captures a first image of a target with the robot in a prescribed position and which captures a second image of the target with the robot in the position resulting from moving the robot a prescribed distance from the aforementioned prescribed position; a calibration data storage unit which stores calibration data that associates the robot coordinate system of the robot and the image coordinate system of the visual sensor; a first acquisition unit which, on the basis of the first image and the calibration data, acquires a first position of the target in the robot coordinate system; a second acquisition unit which, on the basis of the first image and the second image, acquires a second position of the target in the robot coordinate system; and a determination unit which determines whether or not the difference between the first position and the second position is within a prescribed range.

A measurement system includes a multi-axis robot, a measurement unit coupled to the multi-axis robot, and a data processing apparatus, wherein the measurement unit includes one or more imaging devices movable with respect to a reference position of the multi-axis robot, and a position specification device for specifying a position of one or more of the imaging devices with respect to the reference position, wherein the data processing apparatus includes an acquisition part for acquiring a plurality of pieces of captured image data generated by having one or more of the imaging devices capture images at two or more positions, and a measurement part for measuring a distance between the plurality of feature points in a workpiece on the basis of a position of the feature point of the workpiece included in the plurality of pieces of captured image data.

An image processing apparatus that processes an image of a recognition target on a mounting surface captured by an image pickup apparatus, the image processing apparatus includes an extraction unit configured to extract an area from the image based on a first distance from the recognition target to the image pickup apparatus, a height of a designated recognition target, and a second distance from the image pickup apparatus to the mounting surface, and a recognition unit configured to perform recognition processing on the area.

A robot and a robot-based container storage and removal method. The robot comprises: a master control processing unit (110), a pick-and-place mechanism (120) and a marker detection unit (130), wherein according to target storage and removal position information of a target inventory container, the master control processing unit (110) controls a robot body to move to a first horizontal position and controls the pick-and-place mechanism (120) to move to a first height position; when the robot body and the pick-and-place mechanism (120) stop moving, the marker detection unit (130) determines a target pick-and-place marker from a target inventory support to which the target inventory container belongs; and the master control processing unit (110) also calibrates the position of the pick-and-place mechanism (120) according to the position of the target pick-and-place marker, so as to control the calibrated pick-and-place mechanism (120) to perform a storage operation or a removal operation on the target inventory container. By means of the solution, a pick-and-place position of a pick-and-place mechanism (120) of the robot can be precisely positioned and moved, such that the pick-and-place mechanism (120) can quickly and accurately store or remove a target inventory container.

A system includes a machine tool 10, a robot 25 having a camera 31, and a transfer device 35 having the robot 25 mounted thereon, and an identification figure is arranged in a machining area of the machine tool 10.

According to one aspect of the present invention, disclosed is an automatic calibration method for a calibration device connected to a camera that is disposed the end effector of a robot and to a robot controller for controlling the robot. The method comprises the steps of: acquiring, from the camera and the robot controller, a robot-based coordinate system and an image of a marker marked in the work area of the robot (wherein the acquired image and robot-based coordinate system are recorded while the end effector is moved to a plurality of sample coordinates); and estimating the position of a robot coordinate system-based marker by using the acquired image and robot-based coordinate system.

A method for automatically predetermining an intended movement of a manipulator arrangement of a medical system having a medical instrument and a recording means for generating images, wherein the recording means and/or the instrument is guided by the manipulator arrangement. The method includes establishing an intended transformation between a reference stationary in relation to the recording means and a reference stationary in relation to the instrument; monitoring a deviation between the intended transformation and a current transformation between the reference stationary in relation to the recording means and the reference stationary in relation to the instrument; and determining a reset movement of the manipulator arrangement for returning the current transformation to the intended transformation when the deviation satisfies a predetermined condition.

A system and a method using a system for planning a use includes at least one marking, a control and evaluation unit, a database, a display unit, at least one time of flight sensor for a spatial scanning of a real environment, and at least one camera for imaging the real environment. The real environment in a spatial model can be displayed as a virtual environment on the display unit. The marking in the real environment is arranged at a position and has an orientation. The position and the orientation of the marking can be detected at least by the time of flight sensor and the position and orientation of the marking are linked by a virtual sensor model. The virtual sensor model in the spatial model of the virtual environment can be displayed on the display unit at the position and having the orientation of the marking.

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.

A system includes a pose manipulation system operationally that sets a pose of a position measurement system with respect to an object that is to be measured. The system further includes a pose tracking system configured to record a relative pose between a coordinate system associated with the position measurement system and a coordinate system of the object. The pose tracking system records a path along which the position measurement system is enabled to measure 3D coordinates of a surface of a type of an object, wherein recording the path comprises moving the pose manipulation system sequentially through a plurality of poses and recording, at each pose, the relative pose to measure the 3D coordinates. The pose manipulation system follows the path again, and the position measurement system measures the 3D coordinates by applying one or more of the recorded poses.