A server device that incorporates teachings of the present disclosure may include, for example, a memory and a processor. The processor can identify first and second players present at first and second physical locations, to identify first and second boundary and topographical information of the first and second physical locations, to map the first and second boundary and topographical information of the first and second physical locations to a virtual gaming space, to capture first and second position and orientation information for the first and second players, to map the first and second position and orientation information to the virtual gaming space, to generate first and second virtual players corresponding to the first and second players, and to transmit to first goggles information representative of the second virtual player for display superimposed onto a transparent viewing apparatus for viewing of the virtual gaming space. Additional embodiments are disclosed.

The virtual location of a player in a location-based game is determined from the real-world location of the player's client device. The location-based game provides the player access to one or more chat room based on their location. To determine the locations of chat room, a server analyzes player locations in a geographic region, clusters player locations to identify centroids, and adjusts the clusters based on constraints. The server selects chat room locations (e.g., at points of interest) to more evenly balance the number of players in each chat room while complying with one or more restraints on the size of the geographic area served by each chat room.

Provided is a game server for providing a location-based game, including: a location information receiving unit configured to receive location information of a first device from the first device; a game providing unit configured to provide a game based on the location information of the first device to the first device; and an identification information receiving unit configured to receive identification information of the first device from the first device. The location information of the first device is set based on location information of the connected second device, the first device is a device without a GPS (Global Positioning System) function and the second device is a device with the GPS function, the game providing unit allocates a first game environment to the identification information of the first device, and the identification information of the first device includes at least one of a UUID (Universal Unique Identifier), a GUID (Global Unique Identifier), and a Mac Address.

A location-based game system is provided. Such a system may take the form of any device (e.g., a wireless telephone) that includes a locating device (e.g., a GPS system). One such location-based game may operate such that the actual, physical location of a user on a physical playfield corresponds to the location of a virtual character on a virtual playfield. Such location based games are referred to herein as actuality games. In one multiplayer actuality embodiment, two game devices may communicate location, and other, information to a remote database such that the two user's may interact on different physical playfields, but play on the same virtual playfield. A number of wireless communications protocols, self-configuration, and auto-download software applications are also provided to optimize integration with, for example, a wireless telephone.

A method of incentivizing location-based actions by groups is disclosed. A group of users of a game networking system is notified that an incentive reward is to be provided based on a number of members of the group performing a location-based action transgressing a threshold. The incentive reward is provided based on the number of members of the group performing the location-based action transgressing the threshold.

A server device that incorporates teachings of the present disclosure may include, for example, a memory and a processor. The processor can identify first and second players present at first and second physical locations, to identify first and second boundary and topographical information of the first and second physical locations, to map the first and second boundary and topographical information of the first and second physical locations to a virtual gaming space, to capture first and second position and orientation information for the first and second players, to map the first and second position and orientation information to the virtual gaming space, to generate first and second virtual players corresponding to the first and second players, and to transmit to first goggles information representative of the second virtual player for display superimposed onto a transparent viewing apparatus for viewing of the virtual gaming space. Additional embodiments are disclosed.

Aspects of this disclosure relate to rewarding users of an electronic game for real-world physical activity. Further aspects relate to altering virtual items based upon physical activity. An electronic game may comprise or otherwise relate to an online world (such as a “Virtual World”). Users may be represented through customized graphical representations, such as avatars. An account of a user (or entity) may be associated a “virtual region.” A threshold level of real-world physical activity may result in obtaining a reward that may be associated with a virtual item. A reward may be configured to result in: (1) altering visual appearance of a virtual item within a virtual region; (2) altering a virtual characteristic of a virtual item, such that the first user may engage in at least one additional virtual activity using that virtual item; and/or (3) acquiring a new virtual item for a virtual region.

A system and method optimizes game quality by matching players for an online game to one of several virtual games. This matching process may involve filtering the players who wish to play according to various constraint minimizing criteria, packing the players into one or more virtual games to optimize game quality factors of the virtual games, and then instantiating the virtual games to actual online games played by the players. The game packing process may be iterative and may involve adding a new player into a virtual game. Game quality factor (GQF) values prior to and after the placement of the new player in the virtual game may be compared. The comparison of the GQF values may be used, at least in part to determine whether the new player is to remain in the virtual game. Various criteria may be considered in instantiating a virtual game.

A system and processes provide a solution to object identification in images using a game environment to confirm the presence (or absence) of suspected points of interest in the real-world. A game environment uses data gathered by real-world sensors to replicate a real-world location as a gaming environment. Unconfirmed suspected points of interest (locations and/or objects) may be placed into the game environment. Various types of game play may be used to have players interact with the game environment. The actions by players may confirm whether a suspected point of interest is actually present in the real-world. Confirmation data of the presence of points of interest may be forwarded to an external database which may update a map file based on the data provided by player interaction in the game.

A location-based game system is provided. Such a system may take the form of any device (e.g., a wireless telephone) that includes a locating device (e.g., a GPS system). One such location-based game may operate such that the actual, physical location of a user on a physical playfield corresponds to the location of a virtual character on a virtual playfield. Such location based games are referred to herein as actuality games. In one multiplayer actuality embodiment, two game devices may communicate location, and other, information to a remote database such that the two user's may interact on different physical playfields, but play on the same virtual playfield. A number of wireless communications protocols, self-configuration, and auto-download software applications are also provided to optimize integration with, for example, a wireless telephone.