Systems and methods for providing feedback to a user are described. One of the methods includes sending interactive data for rendering on a head mounted display (HMD). The HMD is configured for attachment to a head of a user for playing a game. The method further includes receiving image data associated with a body part of the user while the HMD is worn by the user and the HMD renders interactive content. The method includes tracking a spatial position associated with the body part of the user from the image data of the user. In the method, physical placement of a remote-controlled device at the spatial position associated with the body part of the user is rendered in the HMD as virtual contact with an object in the interactive content.

Systems and methods for providing feedback to a user are described. One of the methods includes sending interactive data for rendering on a head mounted display (HMD). The HMD is configured for attachment to a head of a user for playing a game. The method further includes receiving image data associated with a body part of the user while the HMD is worn by the user and the HMD renders interactive content. The method includes tracking a spatial position associated with the body part of the user from the image data of the user. In the method, physical placement of a remote-controlled device at the spatial position associated with the body part of the user is rendered in the HMD as virtual contact with an object in the interactive content.

A gaming object includes an orientation sensor that generates orientation data in response to the orientation of the gaming object. An actuator that generates interaction data in response to an action of a user. A transceiver sends an RF signal to a game device that indicates the orientation data and the interaction data. The game device generates display data for display on a display device that contains at least one interactive item, and wherein the at least one interactive item is interactive in response to the orientation data and the interaction data.

A method of automatically providing personalized learning activities to users of an online learning platform is described. A quest is built based on an input of at least a first user's educational objective. The quest includes a primary quest that starts with a start node, ends with the end node, and includes a set of intermediate nodes, wherein each node of the primary quest must be traversed by the first user in order to complete the quest. The quest includes at least one secondary quest that starts with a node of the primary quest as its start node and includes a second set of intermediate nodes. As the user selects a node of the quest, educational activities related to its respective concept are presented to the user. The user's progress in the quest is tracked.

A method of automatically providing personalized learning activities to users of an online learning platform is described. A quest is built based on an input of at least a first user's educational objective. The quest includes a primary quest that starts with a start node, ends with the end node, and includes a set of intermediate nodes, wherein each node of the primary quest must be traversed by the first user in order to complete the quest. The quest includes at least one secondary quest that starts with a node of the primary quest as its start node and includes a second set of intermediate nodes. As the user selects a node of the quest, educational activities related to its respective concept are presented to the user. The user's progress in the quest is tracked.

A game system comprising a data processing system and an identification toy element that includes information associated with the identification toy element; wherein the identification toy element is a toy construction element comprising one or more connectors configured for mechanically connecting one or more other toy construction elements to the identification toy element so as to allow a user to construct a toy construction model; and wherein the data processing system is configured to: detect a presence of the identification toy element in a detection area; create an association between a virtual object in a virtual environment and the detected identification toy element; access, when the identification toy element is again placed within a detection area, the information associated with the identification toy element; obtain, based on the accessed information, information about the virtual object associated with the identification toy element; present a representation of the associated virtual object; and to perform a play pattern procedure including controlling the representation of the virtual object.

Systems and methods are disclosed for operating, calibrating, and dynamically optimizing a system for a virtual reality environment where colored marker lights are attached to objects, the objects including players, controllers, and devices related to the game. One or more color cameras are used to view one or more spaces, and track positions and orientations of players and other objects according to the attached marker lights. A hierarchical system of servers may be used to process positions and orientations of objects and provide controls as necessary for the system. A method for color assignment is described as well as a calibration process, and a dynamic optimization process. A synchronization process is also described that ensures that a plurality of cameras and attached servers are properly coordinated. Head-mounted devices may also be used in conjunction with marker lights to provide information regarding players.

Systems and methods are disclosed for operating, calibrating, and dynamically optimizing a system for a virtual reality environment where colored marker lights are attached to objects, the objects including players, controllers, and devices related to the game. One or more color cameras are used to view one or more spaces, and track positions and orientations of players and other objects according to the attached marker lights. A hierarchical system of servers may be used to process positions and orientations of objects and provide controls as necessary for the system. A method for color assignment is described as well as a calibration process, and a dynamic optimization process. A synchronization process is also described that ensures that a plurality of cameras and attached servers are properly coordinated. Head-mounted devices may also be used in conjunction with marker lights to provide information regarding players.

Gaming systems and methods for integrated computer-related and physical game play interactions between a game player, a physical game piece and an electronic device are defined. The physical game piece measures motion quantity and transmits motion data using a signal emitter when the signal emitter is actuated. The electronic device receives the transmitted signal, which a game application inputs along with user input. The game application uses the user input and the transmitted signal to tally game player score data in an accumulator.

Gaming systems and methods for integrated computer-related and physical game play interactions between a game player, a physical game piece and an electronic device are defined. The physical game piece measures motion quantity and transmits motion data using a signal emitter when the signal emitter is actuated. The electronic device receives the transmitted signal, which a game application inputs along with user input. The game application uses the user input and the transmitted signal to tally game player score data in an accumulator.