A method, system, and one or more computer-readable storage media for controlling a robot in the presence of a moving object are provided herein. The method includes capturing a number of frames from a three-dimensional camera system and analyzing a frame to identify a connected object. The frame is compared to a previous frame to identify a moving connected object (MCO). If an unexpected MCO is in the frame a determination is made if the unexpected MCO is in an actionable region. If so, the robot is instructed to take an action.

A robot system including: one or two robot arms which perform work on a target; a shape measurement device which is disposed on the robot arm and measures a shape of the target; and a controller which controls the robot arm based on the shape measurement device, in which the shape measurement device includes a projection device which projects striped pattern light onto the target, an image capturing unit which captures the image of the pattern light, and a processor which calculates the shape of the target based on the captured image by the image capturing device, and in which the projection device includes a light source device which emits linear laser, an optical scanner which generates the pattern light by reflecting the laser from the light source device and by scanning the target, and a scanner driver which outputs a driving signal to drive the optical scanner non-resonantly.

A system for calibration of a robot includes an imaging system (136) including two or more cameras (132). A registration device (120) is configured to align positions of a light spot (140) on a reference platform as detected by the two or more cameras with robot positions corresponding with the light spot positions to register an imaging system coordinate system (156) with a robot coordinate system (150).

A method, system, and one or more computer-readable storage media for controlling a robot in the presence of a moving object are provided herein. The method includes capturing a number of frames from a three-dimensional camera system and analyzing a frame to identify a connected object. The frame is compared to a previous frame to identify a moving connected object (MCO). If an unexpected MCO is in the frame a determination is made if the unexpected MCO is in an actionable region. If so, the robot is instructed to take an action.

A safe optoelectronic sensor (10) is provided for securing a monitored zone (12) comprising at least one machine (26) that forms a hazard area (26a-b), wherein the sensor (10) has a light receiver (16a-b) for generating a received signal from received light from the monitored zone (12); a control and evaluation unit (24) for detecting object positions (28) in the monitored zone (12) from the received signal; and a safe output interface (30) for information acquired from the object positions (28). The control and evaluation unit (24) is here configured to determine the shortest distance between the hazard area (26a-b) and object positions (28) and to provide it at the safe output interface (30).

An additive manufacturing device calibration system and method. In laser control systems, such as the laser control systems used for SL and SLS 3D printers, the laser beam is moved to a location by applying a control value. Often the control value and the location of the laser beam are in different spaces. One calibration system and method involves the input of a number of control values and their corresponding laser beam locations, and the adjusting of the parameters of a mapping function such that the control values generated by applying the mapping function to the input laser beam locations best matches the corresponding input control values.

A laser projection method including the steps of: irradiating, from a laser projection unit, a workpiece that is a measurement object, with a laser while controlling a plurality of mirror angles; imaging the workpiece with a stereo camera, extracting a contour of the workpiece, and calculating a three-dimensional coordinate; calculating a positional relationship between the laser projection unit and the workpiece by comparing the calculated three-dimensional coordinate of the workpiece contour with the minor angle; and performing coordinate transformation of CAD data information and drawing CAD data from the laser projection unit to the workpiece, based on the positional relationship between the laser projection unit and the workpiece. The machining method including the steps of: selecting a component of a tool; assembling the component; imaging the tool assembled; and determining whether or not a desired tool has been assembled.

A camera on a robotic arm end effector is used to locate a workpiece coordinate system transformation in rotation and translation with respect to the end effector coordinate system by successively measuring an offset between a target affixed to the workpiece and its expected location. The target reflects energy from a light beam provided by a light beam source. A beam splitter is used to align the light beam with a line of sight of the camera.

The present disclosure is directed to a method for determining the bending angle on a bending machine, wherein the bending machine includes an upper tool and a lower tool for reshaping a workpiece by bending along a bending line. One or more measuring arrangements are positioned on the bending machine, which together include at least one illumination device and in each case at least one image acquisition device. Each measuring arrangement is assigned a different surface portion of the workpiece which lies laterally adjacent to the bending line and extends along the bending line. A light pattern is imaged on the workpiece by means of the at least one illumination device of a respective measuring arrangement onto the assigned surface portion. The light pattern contains a plurality of zones which are arranged side by side along the bending line.

A camera on a robotic arm end effector is used to locate a workpiece coordinate system transformation in rotation and translation with respect to the end effector coordinate system by successively measuring an offset between a target affixed to the workpiece and its expected location. The target reflects energy from a light beam provided by a light beam source. A beam splitter is used to align the light beam with a line of sight of the camera.