A method for programming a robot in a vision base coordinate is provided. The method includes the following steps. A robot is drawn to an operation point. The coordinates of the operation point in a photo operation are set as a new point. A teaching image is captured and a vision base coordinate system is established. A new point is added according to the newly established vision base coordinate system. When the robot is operating, the robot is controlled to capture an image from a photo operation point. A comparison between the captured image and a teaching image is made. The image being the same as the teaching image is searched according to the comparison result. Whether the vision base coordinate system maintains the same corresponding relation as in the teaching process is checked. Thus, the robot can be precisely controlled.

System and methods to create an immersive virtual environment using a virtual reality system that receives parameters corresponding to a real-world robot. The real-world robot may be simulated to create a virtual robot based on the received parameters. The immersive virtual environment may be transmitted to a user. The user may supply input and interact with the virtual robot. Feedback such as the current state of the virtual robot or the real-world robot may be provided to the user. The user may train the virtual robot. The real-world robot may be programmed based on the virtual robot training.

Modular components form a robotic assembly. the mod-components include modules and tools, each have a set of functions and capabilities, are rapidly configured-reconfigured to function cooperatively, creating a configurable robotic assemblage. Each mod-component incorporates a standardized connector mating with any other standardized connector in an interchangeable manner providing mechanical stability, power, and signals therebetween. Each mod-component incorporates a processor, data storage for mod-component identity, status, and programmable functionality, and for responding to commands. Storage is reprogrammed while the robot is operational, altering both commands and responses. After interconnection, inter-module power and communication are established and each modular component identifies itself and its functionality, thereby providing plug and play configuration.

A robot system using an augmented reality-compatible display, capable of providing information on the status and/or an operation guide of a robot added to an actual image or actual environment, to a user of the robot, so as to improve the efficiency of operations carried out by the user. The robot system includes an actual robot, a controller which controls the actual robot, and an image capturing-displaying device connected to the controller by a wire or by radio. The image capturing-displaying device has a function for capturing an image of a scene including the actual robot and a function for displaying the captured image in real-time. The user can obtain a scene including the actual robot in real-time by directing a camera arranged on the image capturing-displaying device toward the actual robot, and can monitor an augmented reality image.

Disclosed is a method and apparatus for determining a depth of a feature (4) formed in an object (2), the feature (4) having been formed in the object (2) by a cutting tool (38). The apparatus comprises: a camera (42) configured to capture an image of the feature (4) and a portion of the object (2) proximate to the feature (4); and one or more processors operatively coupled to the camera (42) and configured to: detect, in the image, an edge (72) of the feature (4) between the feature (4) and a surface of the object (2); using the detected edge (72), calculate a diameter for a circle (74, 76, 78); acquire a point angle of the cutting tool (38); and, using the calculated diameter and the acquired point angle, calculate a depth value for the feature (4).

A horizontal articulated robot includes a support unit, a movable unit provided in the support unit, from which an end effector is detachable, and a control unit that controls the movable unit, wherein the control unit is provided in the support unit and the end effector is connected to the control unit.

Modular components form a robotic assembly. the mod-components include modules and tools, each have a set of functions and capabilities, are rapidly configured-reconfigured to function cooperatively, creating a configurable robotic assemblage. Each mod-component incorporates a standardized connector mating with any other standardized connector in an interchangeable manner providing mechanical stability, power, and signals therebetween. Each mod-component incorporates a processor, data storage for mod-component identity, status, and programmable functionality, and for responding to commands. Storage is reprogrammed while the robot is operational, altering both commands and responses. After interconnection, inter-module power and communication are established and each modular component identifies itself and its functionality, thereby providing plug and play configuration.

A robot teaching device for teaching a robot offline, capable of setting target, advance and rotation angles of a tool, so that a flat and stable posture of the tool can be obtained. The teaching device has: a storing part which stores a combination of a plurality of processing portion shapes and the target and advance angles associated with each processing portion; a first setting part which sets the target and advance angles associated with the selected processing portion shape, as target and advance angles with respect to the designated processing portion shape; and a second setting part which rotates the tool about a longitudinal axis thereof while maintaining the target and advance angles, so as to calculate the rotation angle of the tool, wherein a height of a face plate of the robot from a horizon plane in the virtual space is maximum at the rotation angle.

System and methods to create an immersive virtual environment using a virtual reality system that receives parameters corresponding to a real-world robot. The real-world robot may be simulated to create a virtual robot based on the received parameters. The immersive virtual environment may be transmitted to a user. The user may supply input and interact with the virtual robot. Feedback such as the current state of the virtual robot or the real-world robot may be provided to the user. The user may train the virtual robot. The real-world robot may be programmed based on the virtual robot training.

Modular components form a robotic assembly, the mod-components include modules and tools, each have a set of functions and capabilities, are rapidly configured-reconfigured to function cooperatively, creating a configurable robotic assemblage. Each mod-component incorporates a standardized connector mating with any other standardized connector in an interchangeable manner providing mechanical stability, power, and signals therebetween. Each mod-component incorporates a processor, data storage for mod-component identity, status, and programmable functionality, and for responding to commands. Storage is reprogrammed while the robot is operational, altering both commands and responses. After interconnection, inter-module power and communication are established and each modular component identifies itself and its functionality, thereby providing plug and play configuration.