To provide a robot system capable of ensuring safety while giving consideration to the occurrence of a trouble in image capture means. A robot system with a camera for monitoring a robot comprises: current position model generation means that generates a current position model for the robot based on current position data about the robot and robot model data about the robot; simulation image generation means that generates a simulation image of the robot viewed from the direction of the camera based on set position data about the camera, set position data about the robot, and the current position model; detection means that compares the simulation image and a monitoring image acquired from the camera to detect the robot in the monitoring image; and safety ensuring means that ensures the safety of the robot system if the detection means does not detect the robot in the monitoring image.

A method for object tracking. The method includes capturing, using a camera device, a sequence of images of a scene, detecting, based on a pattern of local light change across the sequence of images, a light source in the scene, comparing, in response to detecting the light source, a location of the light source in at least one image of the sequence of images and a current position of a transport robot to generate a result, and generating, based on the result, a control signal for moving the transport robot toward the light source such that the light source aligns with a target position within the field-of-view.

A method of assembling a plurality of subcomponents to form a finished component comprises gripping a first subcomponent with a first end-of-arm tool, wherein the first end-of-arm tool is attached to a first robot arm and grasping a second subcomponent with a second end-of-arm tool, wherein the second end-of-arm tool is attached to a second robot arm. Moving the first and second end-of-arm tools to position the first subcomponent relative to the second subcomponent in a pre-assembly position and then moving the first and second end-of-arm tools to engage interface surfaces of the first and second subcomponents. Forming a joint between the first subcomponent and the second subcomponent with a joining tool attached to a joining robot arm to thereby assemble the finished component.

This robot controller causes a robot to follow a target, while a transfer device moves the target, by using a detection result obtained by a movement-amount detecting device that detects the amount by which the transfer device moves the target. When the value of any one of the speed, the acceleration, and the jerk of the target calculated based on the detection result obtained by the movement-amount detecting device or the pattern of the speed, the acceleration, and the jerk deviates from the predetermined reference, the robot controller performs predetermined reporting or stops the robot.

Additive manufacturing systems, methods, and computer readable media may be configured to perform a calibration. Calibrating an additive manufacturing system may include comparing a digital representation of one or more calibration marks to a calibration-CAD model that includes one or more model calibration marks, and applying a calibration adjustment to one or more CAD models based at least in part on the comparison. The digital representation of the one or more calibration marks may have been obtained using a vision system, and the one or more calibration marks may have been printed on a calibration surface according to the calibration-CAD model using an additive manufacturing machine. The calibration adjustment may be configured to align the one or more CAD models with one or more coordinates of the additive manufacturing system.

The utility model provides system and apparatus for communication between different interfaces. The system includes at least an image process module for processing at least an image signal produced from a least an industrial embedded system, a remote control module coupled to at least said image process module for receiving said processed image signal and transmitting it to a remote computer, wherein said remote control module further receiving a control command of said remote computer, and at least a control module coupled to said remote module for receiving and processing said command.

A method and system of controlling an appliance includes: receiving, from a first home appliance, a request to start video image processing for detecting a motion gesture of a user; processing a sequence of image frames captured by a camera corresponding to the first home appliance to identify a first motion gesture; selecting a second home appliance as a target home appliance for the first motion gesture in accordance with one or more target selection criteria, including first target selection criteria based on a location of the user relative to the first home appliance and second target selection criteria based on a level of match between the first motion gesture and a first control gesture corresponding to the second home appliance; and generating a control command to control the second home appliance in accordance with the first control gesture corresponding to the second home appliance.

Provided is a production line that includes a conveying section (2) for conveying a plurality of pallets (8 and 8) along a loop-shaped circulation route, a workpiece setting section (3) for setting workpieces on the pallets (8 and 8), a setting-position measuring section (4) for measuring setting position of the workpiece on the pallets (8 and 8), a production process performing section (5) for performing one or multiple production processes at each of a plurality of locations on the circulation route for the workpieces on the pallets (8 and 8), and a workpiece extracting section (6) for extracting workpieces for which the production processes have been performed from the pallets (8 and 8). At least two of the production processes in the production process performing section (5) are performed while taking into account the setting positions of the workpieces on the pallets (8) measured by the setting-position measuring section (4).

Systems and methods as described herein are directed to the management of a camera system that can involve Pan/Tilt/Zoom (PTZ) cameras and fixed cameras. The fixed cameras are provided with digital PTZ, capabilities through trimming positions and translation matrixes. Through an interface, users can associate different PTZ configurations for a target factory asset in response to an incident or other operation occurring at the asset. When the incident or operation occurs with the target asset, the video and configuration from the corresponding camera can be immediately provided in response.

A loose component supply device in which components scattered on stage are imaged by camera. Because the viewing angle of the camera is >0, a side surface of the component is imaged. Based on the image data of the component, an index value specifying a size of the side surface of the component is calculated. Then, in a case in which the calculated index value matches a set value, it is determined that it is possible to hold the component. In other words, in a case in which there is a certain distance between multiple components, from imaging a side surface of the component, if an index value that specifies the size of the side surface of the component matches the set value, it is determined that it is possible to hold the component.