A skin or skin system for a robot or robotics assembly is provided that includes one or more integral elastomeric links (or bars) (IELs) that are configured for receiving and connection with coupling elements or members (e.g., pivot pins) at the ends of mechanical links/bars. The IELs are also configured to act as a final link of a mechanical linkage made up of these mechanical links to provide a closed chain. For example, the body of each of the IELs, or a portion of the IEL body extending between connection points with the coupling elements of the links/bars of the mechanical linkage, provides a final link in a mechanical linkage forming a closed chain to allow it properly function.

An autonomous companion mobile robot and system may complement the intelligence possessed by a user with machine learned intelligence to make a user's life more fulfilling. The robot and system includes a mobile robotic device and a mobile robotic docking station. Either or both of the mobile robotic device and the mobile robotic docking station may operate independently, as well as operating together as a team, as a system. The mobile robotic device may have an external form of a three-dimensional shape, a humanoid, a present or historical person, some fictional character, or some animal. The mobile robotic device and/or the mobile robotic docking station may each include a fog Internet of Things (IoT) gateway processor and a plurality of sensors and input/output devices. The autonomous companion mobile robot and system may collect data from and observe its users and offer suggestions, perform tasks, and present information to its users.

Disclosed herein is a robot including an output interface including at least one of a display or a speaker, and a processor configured to acquire output data of a predetermined playback time point of content output via the robot or an external device, recognize a first emotion corresponding to the acquired output data, and control the output interface to output an expression based on the recognized first emotion.

A robot device includes a receiver and a sender. The receiver receives a character in a virtual space. The sender sends authorization to operate the robot device to an apparatus in return for the received character.

A reactive media system includes a motion control system having an animated figure with a body and actuators configured to adjust a figure portion of the body in response to interactive data received from one or more interactive data sources. The reactive media system includes a media control system having a tracking camera configured to generate signals indicative of a current position and orientation of the figure portion based on a set of trackers coupled to the figure portion. The media control system includes a media controller configured to receive the signals, determine the current position and orientation based on the signals, and generate data indicative of images to be projected onto an external surface of the figure portion having the current position and orientation. The media control system also includes a projector configured to receive the data from the media controller and project the images onto the external surface.

The present invention relates to an educational robot that includes a body which forms the main portion of the robot. The educational robot also includes a head mounted on the body which is capable of making human facial expressions. In addition, the educational robot includes a plurality of limbs that are capable of making human perceptible gesture. Further, the educational robot includes an interface housed in the body and allows the user to interact with the interface. In an example, the interface allows the user to select a multimedia content from a library of multimedia content. The educational robot includes an imaging device to capture an image of the user to identify the user. Further, the educational robot renders the multimedia content in an interactive and intuitive way.

An artificial intelligence (AI) device, such as a robot, comprises: an output interface to output content in response to a request of a user; a camera to acquire an image of the user; a microphone to acquire a voice signal including a voice content uttered by the user; a processor to determine a characteristic of the user based on the content, the image, and/or the voice signal, and recognize the voice content through a voice recognition mode corresponding to the determined characteristic. The AI device may include a communication interface to forward the voice signal to a remote computer that identifies the characteristic and recognizes the voice content based on the characteristic. According to an embodiment, when an irregular voice is recognized from the acquired voice signal, the processor may recognize a regular voice corresponding to the irregular voice using an artificial intelligence-based learning model.

A robotic platform associated with one or more software services enables remote users to interact with an environment and other humans physically and visually through a robotic surrogate over any distance utilizing the internet. The robotic surrogate is controlled through a non-technical user interface which responds to user control inputs made through natural user arm movements which are tracked in three dimensional space.

A mechanical eyeball includes an outer housing shaped as an ocular surface configured to rotate about a first rotational axis and a second rotational axis that intersect at a fixed center point. The outer is housing is coupled to a mechanical assembly, and the mechanical assembly is contained within a volume associated with the mechanical eyeball. The mechanical assembly can include a stationary gear train and rotatable components that rotate relative to the gear train. The rotatable components are configured to cause rotation of the outer housing about one or more rotational axes. The volume may be substantially the same volume of a human eye. The mechanical assembly is coupled to one or more drivers configured to actuate rotation of the outer housing.

An automatic mobile robot for facilitating activities to improve both neurotypical and autistic children's intellectual and emotional development is disclosed. The mobile robot has a non-humanoid toy shape but includes an expressive face perceived as friendly and approachable by autistic children. The mobile robot is durable and safe for children. It includes auto-play, game, and occupational therapy modes, each of which may be used by a one or more child users at a time. Games and therapeutic activities may be customized to suit each child user's developmental level. The mobile robot includes multiple sensors and components configured to process and express emotion in response to data received from the sensing units and the patterns of child users' interactions with the robot. The robot is programmed to show only limited amounts of negative behavior or emotions to children so that the children do not become afraid and decide not to interact with the robot.