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.

Example implementations relate to robotic operations libraries. An example library may include sets of operation instructions and other information for robotic devices to use to complete desired tasks. For instance, a respective set of operation instructions is determined based on successive simulations in which a virtual robotic device comprising an adjustable configuration initially based on the given configuration of a robotic device performs operations related to a task in an adjustable virtual environment until one or more simulations result in the virtual robotic device performing respective operations that complete the task at a success level that satisfies a predefined threshold. The library may provide a set of instructions for performing operations to a robotic device based on a query received from the robotic device that includes information indicative of a configuration and an environment of the robotic device.

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.

A combination component handling and connecting device connectable to a multi-axis robot for use in moving and connecting components and subassemblies includes a housing and an actuator fixedly connected to the housing. The actuator includes an actuating link movable from a first position to a second position. Connected to the actuating link is an end effector for concurrent movement with the actuating link. The component handling and connecting device includes a clamp having a first jaw and a second jaw. The second jaw is connected to the actuating link for selectively moving the second jaw toward the first jaw operative to engage a component.

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 movable 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.

A robotic customer service agent (“robot”) is provided to a service location. The robot may present a number of security concerns that, whether realized or not, present barriers to acceptance. A robot is provided that is determined to be in compliance with a security criteria. The security criteria may be related to software (e.g., running anti-virus software), hardware (e.g., an added camera is secure), communication (e.g., no unexpected communications), or other aspect. Should the robot be in compliance, it may operate in a secure mode, such as to perform or access more sensitive information. If the robot is not in compliance, the robot is operated in a non-secure mode, such as to block data transmissions, information capturing, or other process or operation that may present a security risk.

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.

Systems and methods for cloud-based surveillance are disclosed. At least one mobile Input Capture Device (ICD) and the at least one computing device are communicatively connected to the cloud-based analytics platform. The at least one mobile ICD captures and transmits input data to the cloud-based analytics platform. The cloud-based analytics platform processes and analyzes input data from the at least one mobile ICD; and generates commands and updates to the at least one mobile ICD based on the processing and analyzing of the input data. Authorized users are operable to access to the cloud-based analytics platform via a user interface over the at least one computing device.

Systems and methods for cloud-based surveillance for a target surveillance area are disclosed. At least two mobile input capture devices (ICDs) are communicatively connected to a cloud-based analytics platform via a data communication device. At least one user device can access to the cloud-based analytics platform. The cloud-based analytics platform automatically analyzes received 2-Dimensional (2D) video and/or image inputs for generating 3-Dimensional (3D) surveillance data and providing 3D display for a target surveillance area. In one embodiment, the at least two mobile ICDs are Unmanned Aerial Vehicles (UAVs).

This invention, pertaining to hospital bed, is a new concept development for automation of services for bedridden patients in the variety of environments. The novelty introduced here is the use of robotic arms affixed on hospital type bed that operates by an electric keypad on the bed side or virtually from a remote location, i.e. a nursing station in the case of a hospital stay. The best mode of operation for this invention would be hospitals, home health care or other health care facilities and settings. This invention is a ground-breaking solution for healing the shortage of trained staff in the health care system.