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 two-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 two-layer track construction that includes machine-readable codes for controlling movement of a mobile agent traveling thereover.

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 modular, connectable loop toy track set capable of being interconnected in a releasable engagement including different shapes and sizes and contains an amount of track sections to form a closed loop. All track sections are comprised of a plurality of square modules. Each square module has size A. A minimum size AA of modular toy track set comprises at least two curve sections that are mechanically connected and a moving body located on said track to form a closed loop track system.

The moving system manufactured as a linear induction motor including a stator made as PCB with printed coils on it and all moving objects having permanent magnets, as a rotor and in such case at any given time only 2 sections of the entire connectable loop track are under temporary power which rolls over to the next section as the moving objects pass through.

A system includes a drivable surface that includes location encoding markings. A mobile agent is provided that includes a drive motor, an imaging system for taking images of the markings, a vehicle wireless transceiver, and a microcontroller operatively coupled to the motor, the imaging system, and the vehicle wireless transceiver. A basestation is provided that includes a controller operatively coupled to a basestation wireless transceiver. Via wireless communication between the wireless transceivers of the mobile agent and the basestation, an action to be implemented by the mobile agent can be determined by the basestation and communicated to the mobile agent, whereupon the microcontroller of the mobile agent controls detailed movement of the mobile agent on the drivable surface based on images taken of the markings of the drivable surface by the imaging system to cause the mobile agent to implement the action on the drivable surface.

A system includes a drivable surface that includes location encoding markings. A mobile agent is provided that includes a drive motor, an imaging system for taking images of the markings, a vehicle wireless transceiver, and a microcontroller operatively coupled to the motor, the imaging system, and the vehicle wireless transceiver. A basestation is provided that includes a controller operatively coupled to a basestation wireless transceiver. Via wireless communication between the wireless transceivers of the mobile agent and the basestation, an action to be implemented by the mobile agent can be determined by the basestation and communicated to the mobile agent, whereupon the microcontroller of the mobile agent controls detailed movement of the mobile agent on the drivable surface based on images taken of the markings of the drivable surface by the imaging system to cause the mobile agent to implement the action on the drivable surface.

A system includes a drivable surface that includes location encoding markings. A mobile agent is provided that includes a drive motor, an imaging system for taking images of the markings, a vehicle wireless transceiver, and a microcontroller operatively coupled to the motor, the imaging system, and the vehicle wireless transceiver. A basestation is provided that includes a controller operatively coupled to a basestation wireless transceiver. Via wireless communication between the wireless transceivers of the mobile agent and the basestation, an action to be implemented by the mobile agent can be determined by the basestation and communicated to the mobile agent, whereupon the microcontroller of the mobile agent controls detailed movement of the mobile agent on the drivable surface based on images taken of the markings of the drivable surface by the imaging system to cause the mobile agent to implement the action on the drivable surface.

A system includes a drivable surface that includes location encoding markings. A mobile agent is provided that includes a drive motor, an imaging system for taking images of the markings, a vehicle wireless transceiver, and a microcontroller operatively coupled to the motor, the imaging system, and the vehicle wireless transceiver. A basestation is provided that includes a controller operatively coupled to a basestation wireless transceiver. Via wireless communication between the wireless transceivers of the mobile agent and the basestation, an action to be implemented by the mobile agent can be determined by the basestation and communicated to the mobile agent, whereupon the microcontroller of the mobile agent controls detailed movement of the mobile agent on the drivable surface based on images taken of the markings of the drivable surface by the imaging system to cause the mobile agent to implement the action on the drivable surface.

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.