An operator telerobotically controls tools to perform a procedure on an object at a work site while viewing real-time images of the work site on a display. Tool information is provided in the operator's current gaze area on the display by rendering the tool information over the tool so as not to obscure objects being worked on at the time by the tool nor to require eyes of the user to refocus when looking at the tool information and the image of the tool on a stereo viewer.

A method for implementing machining tasks for an object. The method identifies location coordinates for a plurality of holes. A task file contains the machining tasks. The robotic devices use the task files to perform the machining tasks. A minimum number of positioning stations is determined where a portion of the machining tasks will be performed by the robotic devices. An ordered sequence for performing the machining tasks is calculated and path a path with the near-minimum distance is determined. Robotic control files are created that cause the robotic devices to perform the machining tasks. The robotic control files are output to the robotic devices to perform the machining tasks to form the plurality of holes.

A manipulator-device controlling method including: a step of receiving manipulation signals for manipulators; a step of calculating a target position of a joint on the basis of the manipulation signals; steps of calculating a maximum distance between the manipulators when the joint is assumed to be placed at the target position; a step of comparing the maximum distance with a predetermined threshold; a step of moving the joint to the target position in the case in which the maximum distance is equal to or less than the predetermined threshold; and a step of stopping the movement of the joint in the case in which the maximum distance is greater than the predetermined threshold.

A synthetic representation of a robot tool for display on a user interface of a robotic system. The synthetic representation may be used to show the position of a view volume of an image capture device with respect to the robot. The synthetic representation may also be used to find a tool that is outside of the field of view, to display range of motion limits for a tool, to remotely communicate information about the robot, and to detect collisions.

A robot simulation device includes a robot-information acquiring unit that performs communication with control units of a plurality of robots included in a robot system and acquires hardware information and software information on the plurality of robots, a change determining unit that determines, on the basis of the acquired software information, whether an operation program is changed, and an evaluating unit that, when the change determining unit determines that the operation program is changed, performs a simulation of operations of the plurality of robots using the hardware information and the software information acquired by the robot-information acquiring unit and evaluates the operation program.

Example systems and methods may allow for parallel operation of robotic devices within a workcell, such as industrial robots controlled to manufacture an output product. One example method includes receiving ordered sequences of operations for a plurality of corresponding robotic devices, determining time-based sequences of operations for each of the robotic devices, where a time-based sequence of operations indicates positions within the workcell at corresponding timesteps of a global timeline, determining one or more potential collisions involving the robotic devices that would result from parallel execution of the time-based sequences of operations within the workcell, modifying the time-based sequences of operations in order to prevent the one or more potential collisions, and providing instructions for parallel execution of the modified time-based sequences of operations at timesteps of the global timeline by the robotic devices within the workcell.

A safety unit is provided for this purpose, and includes a position determining unit, a speed determining unit, a logical product unit, and a stopping unit. When a rotation amount (positional data) of an encoder rotating in connection with a rotation shaft of a servo motor falls within a predetermined limiting range, the position determining unit outputs a command for stopping a motor to a logical product unit. When rotation speed of the encoder rotating in connection with the rotation shaft of the servo motor falls within a predetermined limiting range, the speed determining unit outputs the command for stopping the motor to the logical product unit. This control by the logical product unit requires a stop command from both the position and speed determining units. The logical product unit informs the stopping unit to stop the servo motor to a controller.

The interference determination device includes a distance measurement unit measuring a distance to an object contained in a workspace of a robot; a decimation unit decimating point cloud data obtained by the distance measurement unit, based on a range and a number of points of the point cloud data obtained by the distance measurement unit; an extraction unit extracting point cloud data, contained in a determination region encompassing a robot region that corresponds to a model of the robot positioned in the workspace, from point cloud data after being decimated by the decimation unit; and a determination unit determining that the robot interferes with the object when the point cloud data extracted by the extraction unit is located inside the robot region.

A synthetic representation of a robot tool for display on a user interface of a robotic system. The synthetic representation may be used to show the position of a view volume of an image capture device with respect to the robot. The synthetic representation may also be used to find a tool that is outside of the field of view, to display range of motion limits for a tool, to remotely communicate information about the robot, and to detect collisions.

Example systems and methods may allow for parallel operation of robotic devices within a workcell, such as industrial robots controlled to manufacture an output product. One example method includes receiving ordered sequences of operations for a plurality of corresponding robotic devices, determining time-based sequences of operations for each of the robotic devices, where a time-based sequence of operations indicates positions within the workcell at corresponding timesteps of a global timeline, determining one or more potential collisions involving the robotic devices that would result from parallel execution of the time-based sequences of operations within the workcell, modifying the time-based sequences of operations in order to prevent the one or more potential collisions, and providing instructions for parallel execution of the modified time-based sequences of operations at timesteps of the global timeline by the robotic devices within the workcell.