A modular robot system includes N (N is an integer that is 2 or greater) cube-type unit robots, each of the N cube-type unit robots comprising: a housing in the shape of a regular hexahedron; a step motor installed in the housing; and a controller installed in the housing and for controlling the step motor. The housing has, on one surface thereof, a mounting groove in which a rotary body rotating by means of a rotating shaft of the step motor can be mounted, and, on the other surface of the housing, a connection groove in the same shape, so that by means of a connector to be mounted in the connection groove, connection to another cube-type unit robot is possible, and the housing has identification marks with different shapes from one another on the respective surfaces thereof.

A method, computer-readable medium, and system are disclosed for an interactive storytelling environment. The method comprises identifying a plurality of storytelling devices available to participate in a storytelling experience, at least one of the plurality of the storytelling devices comprising a first beacon device. The method further comprises beginning playback of a first story of the storytelling experience, the first story comprising a first plurality of predetermined actions associated with a predetermined first virtual setting, the first virtual setting mapped to the first beacon device. The method further comprises determining a location of a user using the first beacon device, and during playback of the first story and using at least one of the plurality of storytelling devices, producing one or more of the at least one audiovisual effect corresponding to the first virtual setting based on the determined location of the user.

A vehicle (10) comprising a body (20), a first wheel axle (31) and a second wheel axle (41), whereon one or more wheels (30, 40) is/are mounted, an electric motor (51) and a control unit (52); and wherein the electric motor is connected to the second wheel axle (41); and wherein the electric motor is configured for driving the one or more wheels (40) that is/are mounted on the second wheel axle (41), wherein said vehicle (10) comprises a movement detection unit configured for detecting a movement in the form of a rotation of the vehicle's wheels (30, 40) and/or wheel axles (31, 41); and wherein the control unit (52) is configured for receiving a signal from the movement detection unit when it detects a movement of the vehicle; and wherein the control unit (52) is configured for transmitting a signal to the electric motor (51) when the movement detection unit detects a movement in the form of a rotation of the vehicle's wheels and such that the electric motor (52) continuously powers the one or more wheels (40).

A vehicle (10) comprising a body (20), a first wheel axle (31) and a second wheel axle (41), whereon one or more wheels (30, 40) is/are mounted, an electric motor (51) and a control unit (52); and wherein the electric motor is connected to the second wheel axle (41); and wherein the electric motor is configured for driving the one or more wheels (40) that is/are mounted on the second wheel axle (41), wherein said vehicle (10) comprises a movement detection unit configured for detecting a movement in the form of a rotation of the vehicle's wheels (30, 40) and/or wheel axles (31, 41); and wherein the control unit (52) is configured for receiving a signal from the movement detection unit when it detects a movement of the vehicle; and wherein the control unit (52) is configured for transmitting a signal to the electric motor (51) when the movement detection unit detects a movement in the form of a rotation of the vehicle's wheels and such that the electric motor (52) continuously powers the one or more wheels (40).

An interactive toy including a reader for detecting a marker in a proximity of the interactive toy. The interactive toy also has a sensor for detecting movement of the interactive toy and a memory having programmed instructions and configuration data thereon. The programmed instructions are configured to control a response of the interactive toy to a detection of the marker, the response being defined at least in part by the configuration data. The interactive toy also has a processing unit configured to execute the programmed instructions according to the configuration data when the processing unit is in a play state. The processing unit is further configured to modify the configuration data in response to a combination of a detection of the marker in a proximity of the interactive toy, and a detection of a movement of the interactive toy when the processing unit is in a configuration state.

An interactive toy including a reader for detecting a marker in a proximity of the interactive toy. The interactive toy also has a sensor for detecting movement of the interactive toy and a memory having programmed instructions and configuration data thereon. The programmed instructions are configured to control a response of the interactive toy to a detection of the marker, the response being defined at least in part by the configuration data. The interactive toy also has a processing unit configured to execute the programmed instructions according to the configuration data when the processing unit is in a play state. The processing unit is further configured to modify the configuration data in response to a combination of a detection of the marker in a proximity of the interactive toy, and a detection of a movement of the interactive toy when the processing unit is in a configuration state.

A method and system for activating and cancelling a first or second turn signal indicator for an 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.

A method and system for activating and cancelling a first or second turn signal indicator for an 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.

An apparatus, system, and method for connecting an auxiliary device to a model vehicle are provided. The apparatus includes an accessory port connected to an electronic speed controller and an accessory connector connected to the auxiliary device. The system further includes a battery and accessory port connected to an electronic speed controller. An accessory connector connected to the auxiliary device is designed to connect to the accessory port. The electronic speed controller provides control to the auxiliary device. The method includes providing an electronic speed controller connected to an accessory port and connecting an accessory connector to the accessory port. The accessory connector is further connected to the auxiliary device. The method further includes attaching the auxiliary device to the model vehicle and controlling the auxiliary device via the electronic speed controller.

An apparatus, system, and method for connecting an auxiliary device to a model vehicle are provided. The apparatus includes an accessory port connected to an electronic speed controller and an accessory connector connected to the auxiliary device. The system further includes a battery and accessory port connected to an electronic speed controller. An accessory connector connected to the auxiliary device is designed to connect to the accessory port. The electronic speed controller provides control to the auxiliary device. The method includes providing an electronic speed controller connected to an accessory port and connecting an accessory connector to the accessory port. The accessory connector is further connected to the auxiliary device. The method further includes attaching the auxiliary device to the model vehicle and controlling the auxiliary device via the electronic speed controller.