A throttle emulator system for a model vehicle includes an emulator module and a DCC interface having a connector to permit connection with a DCC command station. The DCC command station is configured to provide digital signals to control the model vehicle. The emulator module is coupled to the DCC interface and configured to transmit command and control signals to the DCC command station, via the DCC interface. The command and control signals are relayed by the DCC command station to control the model vehicle. The emulator module is further configured for wireless communication with a mobile electronic device such that a user can communicate with the emulator module to control the model vehicle through an interface on the mobile electronic device.

A track for a racing car game is described. The width of the track is formed so as to exhibit an optically graded lateral profile that is maintained along the length of the track. The optically graded profile thus provides a means for allocating each lateral position of the track with a unique level of reflectivity. In this way the level of light reflected onto a detector from a vehicle associated light source corresponds to a unique lateral position, and thus provides a diagnostic for determining the lateral position of the vehicle on the track and for maintaining this lateral position along the full length of the track. The track may therefore be considered to comprise a plurality of virtual slots for the vehicle between which the vehicle can easily move and the choice of which is determined by the vehicle's operator.

A track for a racing car game is described. The width of the track is formed so as to exhibit an optically graded lateral profile that is maintained along the length of the track. The optically graded profile thus provides a means for allocating each lateral position of the track with a unique level of reflectivity. In this way the level of light reflected onto a detector from a vehicle associated light source corresponds to a unique lateral position, and thus provides a diagnostic for determining the lateral position of the vehicle on the track and for maintaining this lateral position along the full length of the track. The track may therefore be considered to comprise a plurality of virtual slots for the vehicle between which the vehicle can easily move and the choice of which is determined by the vehicle's operator.

A toy racetrack having an obstacle that is moved into and out of the path of a toy vehicle travelling along the racetrack is provided. The racetrack includes a closed loop track and may include a booster mechanism for propelling a toy vehicle along the track. The obstacle may be formed by a movable web or net with an opening that can be used to catch a toy vehicle traveling along the track. A support tower is located adjacent the track, and an obstacle carrier, optionally including an action figure, is movably mounted to the support tower. The figure holds the net, and the figure and net are movable between a raised position and a lowered position. When the net is in its lowered position, a toy vehicle traveling along the track is captured by the net when the net is manually positioned in a capture position.

A toy racetrack having an obstacle that is moved into and out of the path of a toy vehicle travelling along the racetrack is provided. The racetrack includes a closed loop track and may include a booster mechanism for propelling a toy vehicle along the track. The obstacle may be formed by a movable web or net with an opening that can be used to catch a toy vehicle traveling along the track. A support tower is located adjacent the track, and an obstacle carrier, optionally including an action figure, is movably mounted to the support tower. The figure holds the net, and the figure and net are movable between a raised position and a lowered position. When the net is in its lowered position, a toy vehicle traveling along the track is captured by the net when the net is manually positioned in a capture position.

The toy vehicle track system includes a first track section, a second track section, a third track section, a trigger configured to initiate a launch of a first toy vehicle and a second toy vehicle, and a toy vehicle launcher operatively coupled to the trigger and configured to launch the first toy vehicle onto the first track section and configured to launch the second toy vehicle onto the second track section upon operation of the trigger. The third track section is configured to receive the first toy vehicle from the first track section and configured to receive the second toy vehicle from the second track section such that the first toy vehicle and the second toy vehicle simultaneously travel on the third track section.

The toy vehicle track system includes a first track section, a second track section, a third track section, a trigger configured to initiate a launch of a first toy vehicle and a second toy vehicle, and a toy vehicle launcher operatively coupled to the trigger and configured to launch the first toy vehicle onto the first track section and configured to launch the second toy vehicle onto the second track section upon operation of the trigger. The third track section is configured to receive the first toy vehicle from the first track section and configured to receive the second toy vehicle from the second track section such that the first toy vehicle and the second toy vehicle simultaneously travel on the third track section.

A tracking toy vehicle includes a vehicle body, a left drive wheel, a right drive wheel, a sensing device installed at bottom of the vehicle body for sensing a tracking line, a controller electrically connected to the sensing device, a left driving device for driving the left drive wheel to steer, and a right driving device for driving the right drive wheel to steer. The sensing device includes a first sensor and a second sensor respectively installed on left and right sides of an axle of the vehicle body, for respectively sensing whether the toy vehicle is following the tracking line. The sensing device can identify the tracking line under the vehicle body to confirm the location of the tracking line, and then the controller changes the rotational speed of the left driving device or the right driving device to steer the toy vehicle along the tracking line.

A tracking toy vehicle includes a vehicle body, a left drive wheel, a right drive wheel, a sensing device installed at bottom of the vehicle body for sensing a tracking line, a controller electrically connected to the sensing device, a left driving device for driving the left drive wheel to steer, and a right driving device for driving the right drive wheel to steer. The sensing device includes a first sensor and a second sensor respectively installed on left and right sides of an axle of the vehicle body, for respectively sensing whether the toy vehicle is following the tracking line. The sensing device can identify the tracking line under the vehicle body to confirm the location of the tracking line, and then the controller changes the rotational speed of the left driving device or the right driving device to steer the toy vehicle along the tracking line.

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.