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.

A robot includes an output unit including at least one of a display or a speaker, a camera, and a processor configured to control the output unit to output content, to acquire an image including a plurality of users through the camera while the content is output, to determine a mood of a group including the plurality of users based on the acquired image, and to control the output unit to output feedback based on the determined mood.

Included are a bottom portion having a traveling portion, a body portion having a first pillar portion and a second pillar portion extending in a vertical direction, respectively, from one end and another end in a horizontal direction of the bottom portion, and a top portion including one end connected to an end of the first pillar portion opposite to the bottom portion and including another end connected to an end of the second pillar portion opposite to the bottom portion, an article storage portion that forms an opening with the first pillar portion, the second pillar portion, the top portion, and the bottom portion in such a way that the opening penetrates the body portion, and fixing portions provided in the first and second pillar portions to sandwich the opening and pair up with each other, for fixing an article storage auxiliary instrument.

A robot includes a display configured to display a face image indicating a face of the robot, an input unit configured to receive a customizing request for the face of the robot, and a processor configured to acquire customizing data based on the received customizing request, to generate a face design based on the acquired customizing data, and to control the display to display a face image based on the generated face design.

A remote operation system includes a mobile robot, and an operation terminal configured to communicate with the mobile robot with each other. The mobile robot transmits, to the operation terminal, monitor image information based on a captured image by a camera. The operation terminal receives the monitor image information, and displays, on a terminal display unit, an operation screen including a monitor image based on the captured image. A screen display controller displays the operation screen on the terminal display unit, the operation screen including a first sub screen for displaying the monitor image and a second sub screen different from the first sub screen, and changes a display content of the second sub screen in accordance with a predetermined display mode.

Visually distinguishable robots and methods to manufacture the same are disclosed. An example kit for constructing a robot includes a first component for a framework of the robot, a second component for the framework, and a connector to secure the first and second components in a spatial relationship of a plurality of possible spatial relationships. The spatial relationship is to cause the robot to have a humanly perceptible identity.

A monitor is installed in an eye of a robot, and an eye image is displayed on the monitor. The robot extracts a feature quantity of an eye of a user from a filmed image of the user. The feature quantity of the eye of the user is reflected in the eye image. For example, a feature quantity is a size of a pupillary region and a pupil image, and a form of an eyelid image. Also, a blinking frequency or the like may also be reflected as a feature quantity. Familiarity with respect to each user is set, and which user's feature quantity is to be reflected may be determined in accordance with the familiarity.

An arcade game includes a robot that can be controlled by a player to capture one or more items. The robot may include a stationary base, a lower member rotatably connected to the base to rotate about a first generally vertical axis, a torso member rotatably mounted to the lower member that rotates about a second axis that is generally horizontal; an arm member rotatably mounted to the torso member to rotate about a third axis that is generally parallel to the second axis. A hand portion may include hand-like pincers for grasping and releasing items and may include a sensor to sense contact with an item. A head portion may include a video screen that displays facial features. The head portion may include an image capturing device, such as a video camera.

A robot actor, or character mobility hardware platform, adapted to unleash or provide a wide variety of characters in the physical world. The robot actor enables the often screen-constrained characters to become life-like, interactive participants with nearby people in ways not presently achievable. The robot actor is an untethered, free-roaming robot that is has two (or more) legs, is adapted for high dexterity, is controlled and designed to be self-balancing, and, due to this combination of characteristics, the robot can provide characters with an illusion of life and, in many cases, in correct proportion and scale. The hardware and software of the robot actor will become a new generation of animatronic figures by providing a hardware platform capable of continuously evolving to become more capable through advances in controls and artificial intelligence (AI).

A system for performing automated multi-persona response generation includes processing hardware, a display, and a memory storing a software code. The processing hardware executes the software code to receive input data describing an action and identifying a multiple interaction profiles corresponding respectively to multiple participants in the action, obtain the interaction profiles, and simulate execution of the action with respect to each of the participants. The processing hardware is further configured to execute the software code to generate, using the interaction profiles, a respective response to the action for each of the participants to provide multiple responses. In various implementations, one or more of those multiple responses may be used to train additional artificial intelligence (AI) systems, or may be rendered to an output device in the form of one or more of a display, an audio output device, or a robot, for example.