The present disclosure relates to utilizing idle processing resources of a robot to reduce future burden on such processing resources. In particular, idle processing resources are utilized to identify future scenarios, and generate reactions to such future scenarios. The generated reactions are stored, and quickly retrieved as needed if corresponding identified future scenarios occur.

Systems and methods for configuring a robot for inspecting an inspection surface are disclosed. An example system may include an inspection robot having a payload coupled to at least two inspection sensors and a controller. The controller may include a route profile processing circuit to interpret route profile data for the inspection robot, a configuration determining circuit to determine one or more configurations for the inspection robot in response to the route profile data; and a configuration processing circuit to provide configuration data in response to the determined one or more configurations, the configuration data defining, at least in part, one or more inspection characteristics for the inspection robot.

Systems, apparatus and methods for providing an interactive inspection map are disclosed. An example apparatus for providing an interactive inspection map of an inspection surface may include an inspection visualization circuit to provide an inspection map to a user device in response to inspection data provided by a plurality of sensors operationally coupled to an inspection robot traversing the inspection surface, wherein the inspection map corresponds to at least a portion of the inspection surface. The apparatus may further include a user interaction circuit to interpret a user focus value from the user device, and an action request circuit to determine an action in response to the user focus value. The inspection visualization circuit may further update the inspection map in response to the determined action.

System and methods for traversing an obstacle with an inspection robot are disclosed. An example system may include an inspection robot including an obstacle sensor to interrogate an inspection surface. The example may further include an obstacle sensory data circuit to interpret obstacle sensory data provided by the obstacle sensor, an obstacle processing circuit to determine refined obstacle data, and an obstacle notification circuit to generate and provide obstacle notification data to a user interface device. The example system may further include a user interface circuit to interpret a user request value from the user interface device, and to determine an obstacle response command value in response to the user request value; and an obstacle configuration circuit to provide the obstacle response command value to the inspection robot during the interrogating of the inspection surface.

Systems, methods and apparatus for rapid development of an inspection scheme for an inspection robot are disclosed. An apparatus may include an inspection definition circuit to interpret an inspection description value, and a robot configuration circuit to determine an inspection robot configuration description in response to the inspection description value. The apparatus may further include a configuration implementation circuit, communicatively coupled to a configuration interface of an inspection robot, to provide at least a portion of the inspection robot configuration description to the configuration interface.

Systems, apparatus and methods for providing an inspection map are disclosed. An apparatus for performing an inspection may include an inspection data circuit to interpret inspection data, a robot positioning circuit to interpret position data, and a processed data circuit to link the inspection data with the position data to determine position-based inspection data. The apparatus may further include a user interaction circuit to interpret an inspection visualization request for an inspection map and an inspection visualization circuit to determine the inspection map based on the position-based inspection data, and a provisioning circuit structured to provide the inspection map to a user device.

A method for calculating an arm angle range of a robot arm includes: determining a pose at an tail end position of the robot arm; judging whether an angle of an elbow joint is within a limit thereof when an arm angle is 180 degrees; if yes, constructing a first position matrix characterizing the elbow joint by using the pose and the arm angle; constructing a second position matrix of the elbow joint by using DH parameters of other joints of the robot arm; calculating, according to the first position matrix and the second position matrix, a first arm angle feasible region satisfying a limit of a position joint; judging whether the robot arm has a secondary position joint; and intersecting with the calculated first arm angle feasible region to obtain an arm angle range if no secondary position joint is present at the robot arm.

This disclosure relates to a spatial calibration method and apparatus of a robot ontology coordinate system based on a visual perception device and a storage medium. The method includes: obtaining first transformation relationships; obtaining second transformation relationships; using a transformation relationship between a visual perception coordinate system and an ontology coordinate system as an unknown variable; and resolving the unknown variable based on an equivalence relationship between a transformation relationship obtained according to the first transformation relationships and the unknown variable and a transformation relationship obtained according to the second transformation relationships and the unknown variable, to obtain the transformation relationship between the visual perception coordinate system and the ontology coordinate system.

The collaborative operation support device includes a display device including a display area; and a processor configured to detect, based on an image in which the operator or the robot is represented, a position of a section of the robot in the display area when the operator looks at the robot through the display area, the section associated with an operation mode of the robot specified by means of an input device; select, in accordance with the specified operation mode of the robot, display data corresponding to the specified mode among display data stored in a memory; and display the selected display data in the display area of the display device in such a way that the selected display data is displayed at a position that satisfies a certain positional relationship with the position of the section of the robot in the display area.

A robotic arm assembly is described that incorporates a distributed control arrangement. The robotic arm assembly includes a host computer, a set of robotic arm segments, and a set of actuators, each actuator being interposed between adjacent pairs of the set of robotic arm segments to affect a relative movement between the adjacent pairs of the set of robotic arm segments. The robotic arm assembly further includes an end effector controller configured with a first interface configured to support a first communication link between the end effector controller and the host computer, and a second interface, separate from the first interface. The robotic arm assembly furthermore includes an end effector adapter configured to provide a high speed data interface between the end effector controller and an end effector.