Interactive entertainment devices including a toy magic wand with integrated electronics for, among other things, detecting wand motion and responding accordingly, such as illuminating one or more LEDs, displaying images on one or more LCD displays, playing sound effects or character speech, emitting infrared (IR) signals via one or more IR emitters, or some combination thereof. An exemplary device may include a fairy house or wizard tower playset with integrated electronics for receiving one or more received IR signals and responding or reacting accordingly. For example, depending on the nature of the received IR signals, the electronics may illuminate one or more LEDs, display images on one or more LCD displays, play sound effects or character speech, emit IR signals via one or more IR emitters, or some combination thereof.

Interactive entertainment devices including a toy magic wand with integrated electronics for, among other things, detecting wand motion and responding accordingly, such as illuminating one or more LEDs, displaying images on one or more LCD displays, playing sound effects or character speech, emitting infrared (IR) signals via one or more IR emitters, or some combination thereof. An exemplary device may include a fairy house or wizard tower playset with integrated electronics for receiving one or more received IR signals and responding or reacting accordingly. For example, depending on the nature of the received IR signals, the electronics may illuminate one or more LEDs, display images on one or more LCD displays, play sound effects or character speech, emit IR signals via one or more IR emitters, or some combination thereof.

In an aspect, a toy assembly is provided, and includes a housing, an inner object, at least one sensor and a controller. The inner object is positioned inside the housing and includes a breakout mechanism that is operable to break the housing to expose the inner object. The at least one sensor detects interaction with a user. The controller is configured to determine whether a selected condition has been met based on at least one interaction with the user, and to operate the breakout mechanism to break the housing to expose the inner object if the condition is met. Optionally, the condition is met based upon having a selected number of interactions with the user.

In an aspect, a toy figurine for displaying an animated light pattern includes a main body, a plurality of light-emitting elements inside, and a controller. The light-emitting elements, when unilluminated, are invisible to a user outside the main body, and, when illuminated, are invisible to the user but emit light that is visible through a window of the main body. The controller is programmed to: a) illuminate a first light-emitting element at a first element illumination rate so as to emit first light through the window, b) illuminate a second light-emitting element at a second element illumination rate so as to emit through the light-diffusive window, second light which overlaps with the first light, and c) after step b) has begun, deilluminate the first light-emitting element at a first selected deillumination rate, so as to generate an appearance of light that travels along the window.

A light-up article includes a housing having an aperture at a bottom that receives a lighting device that extends outwardly therefrom. The lighting device includes a spring biased assembly for biasing a contact switch therein to an open position. When force is applied to the article downwardly, springs compress as housing members of the lighting device approach and the contact switch actuates. Actuation results in an electrical circuit outputting light from a light emitter at the top of the lighting device that is viewable through a translucent housing of the article.

A robot is provided. When a value obtained by excluding a gravitational component from an acceleration detected by an acceleration sensor is continuously less than a reference value for a certain time, a travelling state of the robot is determined as frictional surface travelling. A control circuit calculates an attitude angle of the robot from an angular velocity in a pitch direction, which is detected by an angular velocity sensor. When the calculated attitude angle is a lower limit angle or more for a determination time, the control circuit sets the attitude angle at the end of the determination time as an attitude control angle. When the travelling state of the robot is determined as the frictional surface travelling, the control circuit moves a counterweight frontward by a movement amount corresponding to the attitude control angle.

In a robot, after a first value indicating acceleration in the up-and-down axis direction output from an acceleration sensor exceeds a certain threshold value, when any of the first value indicating the acceleration in the up-and-down axis direction, a second value indicating the acceleration in the front-and-back axis direction, and a third value indicating the acceleration in the left-and-right axis direction is determined to exhibit variation exceeding a certain width for a fixed period, the robot determines that a housing of the robot is being held by a user.

A ball is provided forming an inside structure of the snow person, the ball having an inner and outer surface. The ball is a unitary work piece that is free and unconnected to other work pieces. An adhesion surface is disposed on the outer surface of the ball, the adhesion surface provided with nodules that extend away from the surface of the ball to adhere snow while the ball is rolled. Light units are integrated into the surface of the ball and having light emitting portions that extend away from the surface of the ball. A light output of the light units is selected to transmit light through a layer of snow. Connections between the light units situated within the ball connect the light units together.