The present disclosure discloses an information processing system. The system includes at least two toy battle devices and control devices corresponding to the toy battle devices. A first control device is configured to send attack information to a first toy battle device. The first toy battle device is configured to modulate the attack information into a laser signal, and emit the laser signal. A second toy battle device is configured to receive the laser signal by using a laser receiving component, and obtain the attack information by demodulating the laser signal by using a demodulation circuit; and send the attack information to a second control device; determine an attacked status of the second toy battle device according to the attack information; and send a feedback instruction to the second toy battle device, the feedback instruction indicating the attacked status of the second toy battle device.

A customizable adhesive toy playscape is constructed of a combination of printed adhesive playscape tape and other accessories, such as printed stickers, upstanding signs, toy vehicles, and the tape roll core that can be used by children (or adults) for creating imaginary playscape tape worlds for play, education, or other uses. The playscape tape can be part of a single layer track construction that includes machine-readable codes for controlling movement of a mobile agent traveling thereover.

A customizable adhesive toy playscape is constructed of a combination of printed adhesive playscape tape and other accessories, such as printed stickers, upstanding signs, toy vehicles, and the tape roll core that can be used by children (or adults) for creating imaginary playscape tape worlds for play, education, or other uses. The playscape tape can be part of a single layer track construction that includes machine-readable codes for controlling movement of a mobile agent traveling thereover.

An embodiment of an interactive play apparatus may include a camera to capture a projected image, an image recognizer communicatively coupled to the camera to recognize the captured projection image, and a projection responder communicatively coupled to the image recognizer to respond to the recognized projection image. Other embodiments are disclosed and claimed.

A toy vehicle system includes a toy vehicle, a remote-control transmitter and a control unit. The toy vehicle includes a drive with at least two drive motors and at least two roller elements. The roller elements are mutually independently driven rotationally about respective axes of rotation via the drive motors. The toy vehicle further includes at least one steering mechanism for adjusting the directions of orientation of the axes of rotation relative to the longitudinal axis of the vehicle. Input signals of the remote-control are fed into the control unit. The control unit generates output signals that act on the drive and the steering mechanism. In the operating method, the control unit carries out a computational driving simulation and generates therefrom control output signals such that the toy vehicle carries out a vehicle movement according to the computational driving simulation under the action of a virtual operating frictional force.

A system and method for controlling a remote control assembly with precision using signals detected by low-cost brainwave sensors. A brainwave detection unit senses brainwaves and produces corresponding data signals. The brainwave detection unit is capable of detecting the intensity of alpha waves and beta waves without complex waveform analysis. A control unit receives the data signals from the sensors of the brainwave detection unit. The control unit contains circuitry that sets a range for the brainwaves. The range is divided into multiple levels. The control unit produces different control signals as the data signals rise and fall between the levels of the range. A remote controlled assembly is provided that operates in response to the different control signals.

A steering mechanism of a model vehicle which improves steering control accuracy is provided. The steering mechanism of the model vehicle includes the servo motor for steering configured to rotationally drive a steerable wheel of a model vehicle in a steering angle direction, the servo motor for steering being positioned between arm parts and the steerable wheel, the arm parts extending from a vehicle body side of the model vehicle to the steerable wheel. The servo motor for steering includes an output shaft parallel to a steering rotation axis of the steerable wheel and is configured to rotationally drive the steerable wheel by the output shaft.

A steering mechanism of a model vehicle which improves steering control accuracy is provided. The steering mechanism of the model vehicle includes the servo motor for steering configured to rotationally drive a steerable wheel of a model vehicle in a steering angle direction, the servo motor for steering being positioned between arm parts and the steerable wheel, the arm parts extending from a vehicle body side of the model vehicle to the steerable wheel. The servo motor for steering includes an output shaft parallel to a steering rotation axis of the steerable wheel and is configured to rotationally drive the steerable wheel by the output shaft.

A modular toy system comprising a plurality of separate electronic toy modules, each electronic toy module comprising a function device operable to perform a user-perceptible function and a control circuit for controlling the function device; wherein at least a first electronic toy module of the plurality of electronic toy modules comprises a first control circuit, a first function device and a sensor system configured for contactless detection of respective coordinate values of at least two coordinates, each coordinate being indicative of a position or an orientation of at least a second electronic toy module of the plurality of electronic toy modules relative to the first electronic toy module; and wherein the first control circuit is configured to control operation of the first function device based on one or more of the detected coordinate values.

A mobile device includes a body, at least one drive wheel coupled with the body, a control structure configured to automatically control rotational movements of the at least one drive wheel so as to selectively control movement of the body, and a motion detection system coupled with the control structure and configured to detect a plurality of different movements of a user. The control structure controls rotational movements of the at least one drive wheel to effect different movements of the body based upon different detected movements of the user.