A robotic mount is configured to move an entertainment element such as a video display, a video projector, a video projector screen or a camera. The robotic mount is moveable in multiple degrees of freedom, whereby the associated entertainment element is moveable in three-dimensional space. In one embodiment, a system of entertainment elements are made to move and operate in synchronicity with each other, such as to move a single camera via multiple robotic mounts to one or more positions or along one or more paths.

Disclosed herein is a terminal including a communication transceiver configured to establish connection with a first action robot, an input interface configured to receive an execution request of a cluster control mode of an application, and a processor configured to search for at least one other action robot other than the first action robot through the communication transceiver in response to the received execution request, control the communication transceiver to attempt connection with the searched at least one other action robot, and control output of action robot content through the first action robot and the at least one other action robot according to execution of the cluster control mode, when connection with the at least one other action robot is established.

Systems and methods for mounting a robotic arm for use in robotic-assisted surgery, including a mobile shuttle that includes a support member for mounting the robotic arm that extends at least partially over a gantry of an imaging device. Further embodiments include a mounting apparatus for mounting a robotic arm to a base or support column of an imaging device, to a patient table, to a floor or ceiling of a room, or to a cart that extends over the top surface of the patient table.

A robot includes a gripping section adapted to grip an object by open and close a pair of finger sections, a moving device adapted to relatively move the object and the gripping section, and a control device adapted to control the moving device to move the gripping section relatively toward the object, and dispose the pair of finger sections in a periphery of the object, and then control the gripping section to open and close the pair of finger sections in a plane parallel to a mounting surface on which the object is mounted, pinch the object between the pair of finger sections from a lateral side of the object, and grip the object with the gripping section at at least three contact points.

In some embodiments, a functional object-oriented network (FOON) is provided that includes a plurality of functional units each comprising two or more input object nodes that each identify an object and its state before a manipulation motion is performed, a motion node that identifies a manipulation motion that can be performed using the objects, and one or more output object nodes that each identify an object and its state after the manipulation motion has been performed using the objects. In some embodiment, a robot can used the FOON to determine the discrete actions that are required to perform a given task.

A robotic mount is configured to move an entertainment element such as a video display, a video projector, a video projector screen or a staircase. The robotic mount is moveable in multiple degrees of freedom, whereby the associated entertainment element is moveable in three-dimensional space. In one embodiment, a system of entertainment elements are made to move and operate in synchronicity with each other.

Provided is a line-shaped-item securing method including an elastic-body disposing step of disposing an elastic body so as to surround the periphery of one or more line-shaped items; a compressing step of compressing the elastic body, disposed around the periphery of the line-shaped items in the elastic-body disposing step, in a direction perpendicular to the lengthwise direction of the line-shaped items to dimensions smaller than a gap in a robot, through which the line-shaped items are to be passed; a line-shaped-item inserting step of inserting a portion of the line-shaped items, surrounded by the elastic body compressed in the compressing step, into the gap; and an expanding step of releasing the elastic body from compression, with the line-shaped items inserted into the gap in the line-shaped-item inserting step, thereby expanding the elastic body.

An error diagnosis method of a robot includes determining operational status of components of a robot and determining an operational status of a main control process of the robot, generating diagnosis data comprising a data format having an error status level, a name of an error diagnosis processes of the components, and an error code identity (ID) number, packaging diagnosis data of the operational status of the components as diagnosis information in a predetermined data format, storing the diagnosis information in memory.

Systems and methods for virtualized computing or cloud-computing network with distributed input devices and at least one remote server computer for automatically analyzing received video, audio and/or image inputs for providing social security and/or surveillance for a surveillance environment, surveillance event, and/or surveillance target.

Example implementations may relate a robot part including a processor, at least one sensor, and an interface providing wireless connectivity. The processor may determine that the robot part is removablly connected to a particular robotic system and may responsively obtain identification information to identify the particular robotic system. While the robot part is removablly connected to the particular robotic system, the processor may (i) transmit, to an external computing system, sensor data that the processor received from the at least one sensor and (ii) receive, from the external computing system, environment information (e.g., representing characteristics of an environment in which the particular robotic system is operating) based on interpretation of the sensor data. And based on the identification information and the environment information, the processor may generate a command that causes the particular robotic system to carry out a task in the environment.