A gaming system employs bioinformatics to improve gamer performance and enhance the gaming experience. The gaming system monitors biometrics of gamers using gaming accessories having sensors coupled to the gaming accessories (e.g., a mouse with pulse sensor). Biometrics can be used to assess a crisis or panic reaction of the gamer. The system can also assess the state of the game in real time via API feedback, and coach the player on how best to regain control. The system can also predict a gamer's loss of control by monitoring hardware statistics associated with the game, combined with gaming feedback and biometric data, and can determine how best to coach the player to correct problems. Predictive models can be used to predict a gamer's panic attack or loss of control before it occurs. When a crisis occurs, the system can automatically contact the gamer's teammates to assist the gamer.

A method of managing a wireless communication between a plurality of accessory devices and a host device includes, at the host device, establishing a data connection with a plurality of accessory devices, obtaining a radio ID for each accessory device of the plurality of accessory devices, grouping the plurality of accessory devices into at least one OFDMA device and at least one non-OFDMA device based at least partially on the radio IDs, sending a trigger signal to the at least one OFDMA device; and after receiving a first response signal from the at least one OFDMA device in response to the trigger signal, receiving a second response signal from the at least one non-OFDMA device.

A board game comprises one or more game objects such as a game board and game pieces, at least one memory device and at least one controller. Each of the game objects comprise a globally unique identifier and dynamic characteristic values associated with the unique identifier, stored in the memory device, that define the characteristics/attributes of the corresponding game object when used in the game. A user is able to play the game by utilizing the game objects according to their characteristic values. During the course of game play, the events of the game are able to dynamically change the characteristic values of each game object affected by the event. Similarly, outside of game play, external events are also able to dynamically change the characteristic values of a game object. These characteristic values are able to be kept and updated during and in between games.

Examples are disclosed that relate to tracking a pose of a handheld object used with a head-mounted display device. In one example, a method comprises: receiving image data from an image sensing system; detecting a plurality of feature points of the handheld object in a frame of the image data; receiving inertial measurement unit (IMU) data from an IMU of the handheld object; based on detecting the plurality of feature points and receiving the IMU data, determining a first pose of the handheld object; determining that at least a portion of the plurality of feature points is not detected in another frame of the image data; using the IMU data, updating the first pose of the handheld object to a second pose; and body-locking the second pose of the handheld object to a body location on a user wearing the head-mounted display device.

There is provided a system and method for communicating with a first peripheral device, of a plurality of peripheral devices, using a touch-sensitive system that has a processor and a touch surface. According to an exemplary embodiment, a method includes detecting, using the processor, a plurality of touches on the touch surface of the touch-sensitive system that are made by the first peripheral device. The method further includes identifying, using the processor, the first peripheral device based on the plurality of touches on the touch surface of the touch-sensitive system that are made by the first peripheral device. The method additionally includes communicating data, using the processor, to a receptive circuit of the first peripheral device in response to the identifying of the first peripheral device.

A communication play is performed between a master machine and a slave machine. The slave machine can obtain an item according to the result of the communication play and the item is deposited to the master machine. After the communication play ends, if a cartridge is mounted to the slave machine and the master machine and the slave machine perform communication, the item that has been deposited to the master machine is delivered to the slave machine.

A system for allowing a user to remotely access a game includes: a game console; a remote console client configured to receive a game control signal; and a remote console server. The remote console server includes an audio and video encoder configured to receive an audio output and a video output from the game console and to convert the audio output and the video output to a network packet. The remote console server also includes: a game controller emulation unit and a network interface configured to send and receive the network packet. The game controller emulation unit is configured to receive a game controller signal from the game console and to send the game controller signal to the remote console client and to receive a game controller input from the remote console client and send the game controller input to the game console.

A gaming system employs bioinformatics to improve gamer performance and enhance the gaming experience. The gaming system monitors biometrics of gamers using gaming accessories having sensors coupled to the gaming accessories (e.g., a mouse with pulse sensor). Biometrics can be used to assess a crisis or panic reaction of the gamer. The system can also assess the state of the game in real time via API feedback, and coach the player on how best to regain control. The system can also predict a gamer's loss of control by monitoring hardware statistics associated with the game, combined with gaming feedback and biometric data, and can determine how best to coach the player to correct problems. Predictive models can be used to predict a gamer's panic attack or loss of control before it occurs. When a crisis occurs, the system can automatically contact the gamer's teammates to assist the gamer.

An information processing apparatus displays an image on a display, directly communicates wirelessly with another information processing apparatus, and also receives a plurality of operation input data from a plurality of operation devices. Then, the information processing apparatus performs game processing for a communication game based on the plurality of operation input data and received information, and based on the game processing, generates, by screen splitting, game images including images on which operations on the plurality of respective operation devices are reflected, and causes the game images to be displayed on the display.

Systems, apparatus and methods for enabling a mobile station to control a virtual world being executed on a console system are described. The method can include establishing a communication link between the mobile station and a console system, identifying user interface characteristics of the mobile station, and providing a controller application to the mobile station, the controller application being based on the identified user interface characteristics and configured to transform user interface inputs into controller commands. The method can further include receiving signals containing data representing the controller commands from the mobile station over the communication link and determining a sequence of events of the virtual world based on the received controller commands. In one aspect, the controller application can execute in the context of an application on the mobile station.