A customizable toy figure, including a body, and a toy book disposed on at least a portion of the body to entertain a user with at least one story, such that the toy book is oriented in a first direction toward at least a portion of the body.

A customizable toy figure, including a body, and a toy book disposed on at least a portion of the body to entertain a user with at least one story, such that the toy book is oriented in a first direction toward at least a portion of the body.

A 3D animatronic eye is disclosed for fashion products, comprising an eye base and an internal connecting rod mounted on the eye base. The internal connecting rod is placed centrally within the 3D animatronic eye. A lid motor engages to move the lid arm in a predefined angular range. An eye lid is mounted on the lid arm. The motion of the lid arm generates a blinking motion of the eye lid. A sclera is disposed comprising a pupil print. A horizontal motor engages with the sclera to move the sclera linearly in left or right direction. A vertical motor engages with the sclera to move the sclera linearly in upward or downward direction. A housing mounted on the eye base, covers the sclera. A control unit comprises executable program instructions to control the motion of the lid motor, the horizontal motor, and the vertical motor.

A 3D animatronic eye is disclosed for fashion products, comprising an eye base and an internal connecting rod mounted on the eye base. The internal connecting rod is placed centrally within the 3D animatronic eye. A lid motor engages to move the lid arm in a predefined angular range. An eye lid is mounted on the lid arm. The motion of the lid arm generates a blinking motion of the eye lid. A sclera is disposed comprising a pupil print. A horizontal motor engages with the sclera to move the sclera linearly in left or right direction. A vertical motor engages with the sclera to move the sclera linearly in upward or downward direction. A housing mounted on the eye base, covers the sclera. A control unit comprises executable program instructions to control the motion of the lid motor, the horizontal motor, and the vertical motor.

This describes a treatment method for autism/ASD intended to induce greater intrinsic motivation to make eye contact in affected children. The treatment method incorporates an artificial demonstration of the phenomenon of eye contact, and that method is described herein along with the principles of action of the treatment and the necessary procedure to perform it. Also described are two embodiments of a therapy tool that can be used to effect the demonstration: first, an item in the form of a cuboid with animatronic eyes affixed to one side, and second, another in the form of a stuffed dog.

This describes a treatment method for autism/ASD intended to induce greater intrinsic motivation to make eye contact in affected children. The treatment method incorporates an artificial demonstration of the phenomenon of eye contact, and that method is described herein along with the principles of action of the treatment and the necessary procedure to perform it. Also described are two embodiments of a therapy tool that can be used to effect the demonstration: first, an item in the form of a cuboid with animatronic eyes affixed to one side, and second, another in the form of a stuffed dog.

A robot includes an operation control unit that selects a motion of the robot, a drive mechanism that executes a motion selected by the operation control unit, and a remaining battery charge monitoring unit that monitors a remaining charge of a rechargeable battery. Behavioral characteristics of the robot change in accordance with the remaining battery charge. For example, a motion with a small processing load is selected at a probability that is higher the smaller the remaining battery charge. Referring to consumption plan data that define a power consumption pace of the rechargeable battery, the behavioral characteristics of the robot may be caused to change in accordance with a difference between the remaining battery charge scheduled in the consumption plan data and the actual remaining battery charge.

A robot includes an operation control unit that selects a motion of the robot, a drive mechanism that executes a motion selected by the operation control unit, and a remaining battery charge monitoring unit that monitors a remaining charge of a rechargeable battery. Behavioral characteristics of the robot change in accordance with the remaining battery charge. For example, a motion with a small processing load is selected at a probability that is higher the smaller the remaining battery charge. Referring to consumption plan data that define a power consumption pace of the rechargeable battery, the behavioral characteristics of the robot may be caused to change in accordance with a difference between the remaining battery charge scheduled in the consumption plan data and the actual remaining battery charge.

A transformable building block comprises a body configured to receive a connector post or other portion of another building element, an appendage movably coupled to the body, and a post configured to protrude from the body and retract into the body. Inserting a connector post into the body of the transformable building block may cause the appendage to move and the post to protrude from the body. Removing the connector post from the body may cause the post to retract into the body.

An animatronic device includes a mechanical eyeball configured to rotate about a first rotational axis and a second rotational axis that intersect at a fixed center point. A controller is configured to generate eye movement instructions that cause the animatronic device to rotate the mechanical eyeball about at least one of the first rotational axis and the second rotational axis. The eye movement instructions are generated based on an eye tracking system used to track movement of an eye of a user. The controller maps the tracked eye movement to movement of the mechanical eyeball and generates eye movement instructions based on the mapping.