Accurate wiring work shall be efficiently performed when a module group included in a control system for an industrial machine is installed. An installation support apparatus includes an image information acquisition part configured to acquire a camera image of a module included in a control system for an industrial machine, a design information acquisition part configured to specify the module on the basis of the camera image, and acquire design information relevant to wiring of the module, and a projection information processing part configured to generate a projection image based on the design information, allowing to be projected onto a position corresponding to the camera image.

A recognition device includes: an image generator configured to acquire a control signal for displaying an image on a display device of a machine tool, the control signal being output from a display control device of the machine tool, and generate an image to be displayed on the display device, based on the acquired control signal; and an information generator configured to recognize at least one of state and control content of the machine tool, contained in the image, and generate machine information.

An operation management system configured to acquire measured values of a workpiece from a numerical controller which controls a machine tool to measure the workpiece is provided with a measurement macro receiving unit configured to read a measurement macro for controlling the measurement from the numerical controller, a measurement macro analysis unit configured to analyze the measurement macro to identify the name of a measurement result variable loaded with the measured values, and a measurement result read-out unit configured to read out the value of the measurement result variable from the numerical controller. The operation management system easily acquires the result of the workpiece measurement from the numerical controller.

Systems and methods are provided for verifying the placement of tows by a robot. One embodiment includes a robot that includes an end effector that lays up tows, actuators that reposition the end effector, a memory storing a Numerical Control (NC) program, and a robot controller that directs the actuators to reposition the end effector based on the NC program, and instructs the end effector to lay up tows based on the NC program. The system also includes a sensor system comprising an imaging device that acquires images of the tows as the tows are laid-up, a measuring device that generates input as tows are laid-up by the end effector, and a sensor controller that receives images from the imaging device and the input from the measuring device, and updates stored data to correlate the images with instructions in the NC program, based on the input.

A vision system may include a first camera and a second camera mounted for stereoscopic monitoring of a work environment, a support platform for support of a workpiece in the work environment, a first reference plate operably coupled to the support platform to provide a first frame of reference for three dimensional location of objects in the work environment, a power tool operable in the work environment under control of a tool controller, and a motion monitor operably coupled to the first and second cameras to determine location of the tool in the work environment based on a comparison of a reference point on the tool to a position of reference points on the reference plate. A perspective view of the support platform by the first and second cameras may be changeable, and the system may further include a second reference plate to define a second frame of reference for three dimensional location of objects responsive to the perspective view of the support platform being changed.

Systems and methods are provided for verifying the placement of tows by a robot. One embodiment includes a robot that includes an end effector that lays up tows, actuators that reposition the end effector, a memory storing a Numerical Control (NC) program, and a robot controller that directs the actuators to reposition the end effector based on the NC program, and instructs the end effector to lay up tows based on the NC program. The system also includes a sensor system comprising an imaging device that acquires images of the tows as the tows are laid-up, a measuring device that generates input as tows are laid-up by the end effector, and a sensor controller that receives images from the imaging device and the input from the measuring device, and updates stored data to correlate the images with instructions in the NC program, based on the input.

A welding apparatus includes a multi-axis robotic arm having a first end; a welding tool attached to the first end; an image acquisition device attached to the first end and having a light filtering system; the image acquisition device is configured to monitor a welding target and to provide an image of the welding target to an operator; a control unit is configured to control the robotic arm and the welding tool; an input interface for a human operator is associated to the control unit and is configured to provide an input signal to the control unit and to control the robotic arm and welding tool substantially in real time.

Systems and methods are provided for verifying the placement of tows by a robot. One embodiment includes a robot that includes an end effector that lays up tows, actuators that reposition the end effector, a memory storing a Numerical Control (NC) program, and a robot controller that directs the actuators to reposition the end effector based on the NC program, and instructs the end effector to lay up tows based on the NC program. The system also includes a sensor system comprising an imaging device that acquires images of the tows as the tows are laid-up, a measuring device that generates input as tows are laid-up by the end effector, and a sensor controller that receives images from the imaging device and the input from the measuring device, and updates stored data to correlate the images with instructions in the NC program, based on the input.

A method for operating a medical-robotic device is provided. The robotic device includes a number of components able to be moved autonomously in an environment of the robotic device. Planning data for an autonomous movement or constraint of at least one subset of the movable components is provided to the robotic device. A movement or constraint of the corresponding movable components to be carried out autonomously by the robotic device is planned based on the planning data provided. The planned movement or constraint is visually presented. A way for an operator to exert influence on the planned movement or constraint is provided, and the movement or constraint is autonomously carried out as a function of the influence exerted.

A vision system may include a first camera and a second camera mounted for stereoscopic monitoring of a work environment, a support platform for support of a workpiece in the work environment, a first reference plate operably coupled to the support platform to provide a first frame of reference for three dimensional location of objects in the work environment, a power tool operable in the work environment under control of a tool controller, and a motion monitor operably coupled to the first and second cameras to determine location of the tool in the work environment based on a comparison of a reference point on the tool to a position of reference points on the reference plate. A perspective view of the support platform by the first and second cameras may be changeable, and the system may further include a second reference plate to define a second frame of reference for three dimensional location of objects responsive to the perspective view of the support platform being changed.