A method and system for activating and cancelling a first or second turn signal indicator for a radio-controlled (R/C) vehicle are provided. The method may include determining that the R/C vehicle is stationary and reading a rotation of a steering input to a stationary activation threshold. In addition, the method may include activating the turn signal indicator on a side of the R/C vehicle and setting an active turn signal indicator to on. Further actions in the method may involve determining that the R/C vehicle is in motion and reading a rotation of the steering input to a moving initiation threshold. Still further actions may include reading a rotation of the steering input in another direction to a moving cancellation threshold and deactivating the first or second turn signal indicator and setting the active turn signal indicator to off.

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.

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.

Systems and methods for stabilizing the steering and throttle of a radio-controlled (RC) vehicle are described herein. More specifically, sensors and circuitry are configured to control the wheel speed and wheel direction of a RC vehicle based on rotational information. In operation, one or more sensors may be configured to receive angular rotational information associated with a rotation of the RC vehicle. The rotational information may define a rotation of the RC vehicle around one or more axes of the RC vehicle. The circuitry may be configured to receive the angular rotation information associated with the rotation of the RC vehicle from the one or more sensors, and control a wheel speed and/or a wheel direction of at least one wheel of the RC vehicle based at least in part on (i) command data received from a controller associated with the RC vehicle and (ii) the received angular rotation information.

Systems and methods for stabilizing the steering and throttle of a radio-controlled (RC) vehicle are described herein. More specifically, sensors and circuitry are configured to control the wheel speed and wheel direction of a RC vehicle based on rotational information. In operation, one or more sensors may be configured to receive angular rotational information associated with a rotation of the RC vehicle. The rotational information may define a rotation of the RC vehicle around one or more axes of the RC vehicle. The circuitry may be configured to receive the angular rotation information associated with the rotation of the RC vehicle from the one or more sensors, and control a wheel speed and/or a wheel direction of at least one wheel of the RC vehicle based at least in part on (i) command data received from a controller associated with the RC vehicle and (ii) the received angular rotation information.

A system for providing autonomous driving of a radio controlled vehicle through an ambient environment is disclosed herein. The system can include a modular device with at least one sensor configured to generate signals associated with characteristics of the ambient environment, a bed plate configured to be mechanically coupled to the RC vehicle, and a modular control circuit configured to be mechanically coupled to the bed plate and communicably coupled to the modular device, wherein the modular control circuit is configured to be communicably coupled to hardware of the RC vehicle and control the RC vehicle in response to commands received from the modular device.

A control device for a model car is provided. The control device comprises: a rotation sensor configured to detect a rotation number of a first wheel and a rotation number of a second wheel of a model car; and a controller configured to perform driving control of a driving source of the model car such that a rotation number difference between the first wheel and the second wheel is reduced when the rotation number difference is greater than or equal to a threshold.

A cruise control system and method for a model vehicle are provided. The system may include a transmitter having a throttle input to produce a throttle command and a cruise control set input. The system includes a receiver for receiving the throttle command and a speed controller for providing a motor command to a motor of a model vehicle. The speed controller provides a motor command based upon the throttle command at a point when the cruise control set input is activated. The method for providing cruise control for a model vehicle includes receiving a throttle command from a throttle input and activating a cruise control set input. The method may include recording the throttle command as a cruise control throttle input at a point when the cruise control set input is activated and sending a motor command to a motor while the cruise control set input is activated.