A speech remote control device includes a speech input unit, a speech identification unit, a motion setting unit, a transmit unit and a receiving unit. The speech input unit converts a received speech command into a speech signal. The speech identification unit receives the speech signal, and transmits an encoded message. The motion setting unit receives and decodes the encoded message to generate a combination message with a proceeding control command and a turning control command, or comprising a series of sub-combination messages. The transmitting unit receives and transmits the combination message to the receiving unit provided on the remote control car. The remote control car is driven by the receiving unit to automatically change direction or make more than one turn during proceeding. Thus, only one speech command controls the remote control car to simultaneously proceed and make a turn without sending any additional command for changing direction.

A speech remote control device includes a speech input unit, a speech identification unit, a motion setting unit, a transmit unit and a receiving unit. The speech input unit converts a received speech command into a speech signal. The speech identification unit receives the speech signal, and transmits an encoded message. The motion setting unit receives and decodes the encoded message to generate a combination message with a proceeding control command and a turning control command, or comprising a series of sub-combination messages. The transmitting unit receives and transmits the combination message to the receiving unit provided on the remote control car. The remote control car is driven by the receiving unit to automatically change direction or make more than one turn during proceeding. Thus, only one speech command controls the remote control car to simultaneously proceed and make a turn without sending any additional command for changing direction.

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 first battling device has one or more processors, memory, one or more wireless receiving components; and one or more driving component for moving the first battling device. The first battling device receives a radio signal by using at least one of the wireless receiving components, the radio signal being broadcast by a wireless transmitting component of a second battling device that is distinct from the first battling device. The first battling device determines a position of the first battling device relative to the second battling device according to respective position information of the at least one of the wireless receiving components of the first battling device that have received the radio signal. The first battling device performs a predetermined action according to the respective position information of the at least one of the wireless receiving components of the first battling device that have received the radio signal.

A first battling device has one or more processors, memory, one or more wireless receiving components; and one or more driving component for moving the first battling device. The first battling device receives a radio signal by using at least one of the wireless receiving components, the radio signal being broadcast by a wireless transmitting component of a second battling device that is distinct from the first battling device. The first battling device determines a position of the first battling device relative to the second battling device according to respective position information of the at least one of the wireless receiving components of the first battling device that have received the radio signal. The first battling device performs a predetermined action according to the respective position information of the at least one of the wireless receiving components of the first battling device that have received the radio signal.

A robotic activity system, which includes a board and an autonomous robotic device, is described herein. The board may display a line and one or more color patterns. The robotic device may traverse the line using one or more integrated sensors. For example, sensor data may include light intensity data for visible light reflected or emitted by the board. The sensor data may be analyzed to 1) ensure the robotic device follows the line and/or 2) detect color sequences associated with color patterns shown on the board. Upon detection of a color sequence, the robotic device may attempt to match the color sequence with a known color pattern definition. The color pattern definition may be associated with a function to be performed by the robotic device. Using multiple sets of color patterns and associated functions allows the robotic device to move in a variable and potentially unpredictable fashion.

A robotic activity system, which includes a board and an autonomous robotic device, is described herein. The board may display a line and one or more color patterns. The robotic device may traverse the line using one or more integrated sensors. For example, sensor data may include light intensity data for visible light reflected or emitted by the board. The sensor data may be analyzed to 1) ensure the robotic device follows the line and/or 2) detect color sequences associated with color patterns shown on the board. Upon detection of a color sequence, the robotic device may attempt to match the color sequence with a known color pattern definition. The color pattern definition may be associated with a function to be performed by the robotic device. Using multiple sets of color patterns and associated functions allows the robotic device to move in a variable and potentially unpredictable fashion.

A device control system, method, and apparatus are provided. The system includes a control device and at least two battle game devices. The control device is configured to: establish a connection to a first battle game device, and send a control instruction to the first battle game device during a battle game according to a received external control operation. The first battle game device is configured to battle according to the control instruction. The second battle game device is configured to: obtain a relative position of the first battle game device during the battle game, and automatically battle according to the relative position.

A device control system, method, and apparatus are provided. The system includes a control device and at least two battle game devices. The control device is configured to: establish a connection to a first battle game device, and send a control instruction to the first battle game device during a battle game according to a received external control operation. The first battle game device is configured to battle according to the control instruction. The second battle game device is configured to: obtain a relative position of the first battle game device during the battle game, and automatically battle according to the relative position.