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.

The present invention provides a self-righting model vehicle.

The disclosure relates to a story machine, a control method and control device thereof, a storage medium and a story machine player system are provided. The story machine includes circuitry configured to detect movement indication information for indicating a first movement path of the story machine; control the story machine to move along the first movement path based on the detected movement indication information; detect play indication information for indicating multimedia information; control the story machine to stop moving in response to detecting the play indication information; and play the multimedia information based on the detected play indication information.

An operation replay module comprises: a manipulation command input unit that receives a manipulation command from a user; an output unit that outputs a control signal corresponding to the manipulation command from the manipulation command input unit; a memory that stores history of the manipulation command; a replay command input unit that receives a replay command from the user; and a micom that outputs a control signal corresponding to the history of the manipulation command stored in the memory to the output unit, if the micom receives the replay command from the replay command input unit.

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 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 drivable surface includes a plurality of segments that can be arranged according to any desired configuration. One or more mobile agents are configured to automatically explore the drivable surface so as to ascertain the positions, orientations, and/or configurations of the various segments, as well as how they are connected to one another. The information collected during such exploration can be transmitted to a host device or other location, where a virtual representation of the drivable surface can be constructed based on the collected information.

A drivable surface includes a plurality of segments that can be arranged according to any desired configuration. One or more mobile agents are configured to automatically explore the drivable surface so as to ascertain the positions, orientations, and/or configurations of the various segments, as well as how they are connected to one another. The information collected during such exploration can be transmitted to a host device or other location, where a virtual representation of the drivable surface can be constructed based on the collected information.

A control system to locate a motorized entity on a display having an electronic device with a display is provided. The electronic device may include a microphone and an electronic device integrated circuit with a set of entity locating software instructions with a capability to generate and display a sequence of pixels in a location pattern, and to further receive an audio output detection signal from the microphone. The entity may include a speaker and one or more sensors in communication with an entity integrated circuit including a set of entity control software instructions. The one or more sensors may be capable of detecting pixels and to send a pixel detection signal to the entity integrated circuit upon detection thereof.