A coding toy includes a control object (a figure body) having a control unit, an input unit and an output unit, and a part (an icon block) having a code identifier (an icon) that corresponds to a control detail of the control object. The control unit of the control object obtains code identifier information and positional information from the code identifier indicated by the part disposed in a predetermined position and the position of the part and controls the output unit to a control detail and in a control sequence that are determined by the code identifier information and the positional information.

A coding toy includes a control object (a figure body) having a control unit, an input unit and an output unit, and a part (an icon block) having a code identifier (an icon) that corresponds to a control detail of the control object. The control unit of the control object obtains code identifier information and positional information from the code identifier indicated by the part disposed in a predetermined position and the position of the part and controls the output unit to a control detail and in a control sequence that are determined by the code identifier information and the positional information.

An action robot may include a main body, at least one joint, and at least one limb configured to be rotatably connected to the main body via the joint. The joint may be configured to provide elastic force in a direction in which the limb is unfolded or pulled away from the main body and a wire connected to the limb to pull the limb in a direction in which the limb is folded or pulled toward the main body. The wire may be connected to an elevation rod provided inside the main body. A drive assembly may be provided outside the main body and be configured to lift the elevation rod. A rod spring may be provided and configured to provide a downward elastic force to the elevation rod. A wire support provided within the main body may be configured to support the wire.

An action robot may include a main body, at least one joint, and at least one limb configured to be rotatably connected to the main body via the joint. The joint may be configured to provide elastic force in a direction in which the limb is unfolded or pulled away from the main body and a wire connected to the limb to pull the limb in a direction in which the limb is folded or pulled toward the main body. The wire may be connected to an elevation rod provided inside the main body. A drive assembly may be provided outside the main body and be configured to lift the elevation rod. A rod spring may be provided and configured to provide a downward elastic force to the elevation rod. A wire support provided within the main body may be configured to support the wire.

Provided herein is a character control system includes a strap configured to removably couple to a prop of a performer. A controls assembly is disposed within a portion of the strap. The controls assembly includes a plurality of control features. A controller is configured to couple to the controls assembly and an actuator of a puppet. The controller is configured to control the actuator to move a part of the puppet in response to actuation of a control feature of the plurality of control features by the performer.

Smart Entertainment Technology uses technology to create an enhanced, real-world experience or adventure, and helps users explore, communicate, learn, and solve puzzles, creating a richer, more immersive experience. In one embodiment, a method includes identifying a plurality of patrons in an entertainment attraction using a contactless sensor. The entertainment attraction comprises a room, and each wall of the room comprises modular, interconnected, adaptable full-wall digital displays. The method further includes determining a digital attraction experience suitable for each of the patrons based on the age and attraction preferences of each of the patrons. The method additionally includes formatting for display on the modular full-wall digital displays content associated with the determined digital attraction experience. The method further includes determining an interactive gesture performed by one of the patrons, and formatting for display on the full-wall digital displays, appropriate content responsive to the interactive gesture.

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 arm assembly includes a servo coupled to the chest of the robot, an upper arm driven by the servo, a forearm rotatably coupled to the upper arm, and a forearm transmission member comprising a first end rotatable with respect to the chest and a second end coupled to the forearm. The upper arm, the forearm and the forearm transmission member are arranged in such a way that the forearm rotates when the upper arm rotates with respect to the chest.

The present invention relates to a pop-up toy which is mounted at a random location, operates by means of a moving object which moves from outside, and thus transforms from a first from into a second form, thereby enhancing amusement of the play.

An apparatus includes a housing, a rotational motor situated within the housing, an eccentric load adapted to be rotated by the rotational motor, and a plurality of legs each having a leg base and a leg tip at a distal end relative to the leg base. The legs are coupled to the housing at the leg base and include at least one driving leg constructed from a flexible material and configured to cause the apparatus to move in a direction generally defined by an offset between the leg base and the leg tip as the rotational motor rotates the eccentric load.