A method is provided, including: tracking a location of a head-mounted display (HMD); tracking a gaze of a user of the HMD; generating video depicting a view of a virtual environment for the HMD based on the gaze of the user of the HMD; initiating wireless transmission of the video to the HMD for display on the HMD to the user, wherein initiating the wireless transmission includes setting a beamforming of a wireless transceiver towards the location of the head-mounted display; processing signal quality feedback received from the HMD to determine a quality of the wireless transmission; responsive to a loss in the quality of the wireless transmission, then adjusting the beamforming of the wireless transceiver.

A method is provided, including: tracking a location of a head-mounted display (HMD); tracking a gaze of a user of the HMD; generating video depicting a view of a virtual environment for the HMD based on the gaze of the user of the HMD; initiating wireless transmission of the video to the HMD for display on the HMD to the user, wherein initiating the wireless transmission includes setting a beamforming of a wireless transceiver towards the location of the head-mounted display; processing signal quality feedback received from the HMD to determine a quality of the wireless transmission; responsive to a loss in the quality of the wireless transmission, then adjusting the beamforming of the wireless transceiver.

A video server is configured to provide streaming video to players of computer games over a computing network. The video server can provided video of different games to different players simultaneously. This is accomplished by rendering several video streams in parallel using a single GPU (Graphics Processing Unit). The output of the GPU is provided to graphics processing pipelines that are each associated with a specific client/player and are dynamically allocated as needed. A client qualifier may be used to assure that only clients capable of presenting the streaming video to a player at a minimum level of quality receive the video stream. Video frames provided by the video server optionally include overlays added to the output of the GPU. These overlays can include voice data received from another game player.

A video server is configured to provide streaming video to players of computer games over a computing network. The video server can provided video of different games to different players simultaneously. This is accomplished by rendering several video streams in parallel using a single GPU (Graphics Processing Unit). The output of the GPU is provided to graphics processing pipelines that are each associated with a specific client/player and are dynamically allocated as needed. A client qualifier may be used to assure that only clients capable of presenting the streaming video to a player at a minimum level of quality receive the video stream. Video frames provided by the video server optionally include overlays added to the output of the GPU. These overlays can include voice data received from another game player.

A split hierarchy graphics processor system including a master node executing a virtual reality (VR) application responsive to input from a client device received over a network to generate primitives for in a VR environment. The graphics processor system including render nodes performing rendering based on the primitives for views into the VR environment taken from a location in the VR environment, the views corresponding to a grid map of the VR environment. Each of the render nodes renders, encodes and streams a corresponding sequence of frames of a corresponding view to the client device. The processor system including an asset library storing input geometries for the objects used for building the VR environment, wherein the objects in the asset library are accessible by the master node and the render nodes.

A split hierarchy graphics processor system including a master node executing a virtual reality (VR) application responsive to input from a client device received over a network to generate primitives for in a VR environment. The graphics processor system including render nodes performing rendering based on the primitives for views into the VR environment taken from a location in the VR environment, the views corresponding to a grid map of the VR environment. Each of the render nodes renders, encodes and streams a corresponding sequence of frames of a corresponding view to the client device. The processor system including an asset library storing input geometries for the objects used for building the VR environment, wherein the objects in the asset library are accessible by the master node and the render nodes.

A video game client on a client device may, for example, be operated by a broadcasting game player, and the client device may capture video generated by a video game client and transmit (e.g., stream) the video to one or more spectators. The video game client may include a local server component, such as a hypertext transfer protocol (HTTP) server, which executes locally at the client device. The local server component may be employed to provide statistical information from the video game to a local client component, such as a web interface. The statistical information provided by the local server component may be included in one or more visual display items that are generated by the client device. The visual display items may be included in the video that is captured and transmitted by the client device, thereby potentially providing live streaming statistical information to spectators of the video game.

A video game client on a client device may, for example, be operated by a broadcasting game player, and the client device may capture video generated by a video game client and transmit (e.g., stream) the video to one or more spectators. The video game client may include a local server component, such as a hypertext transfer protocol (HTTP) server, which executes locally at the client device. The local server component may be employed to provide statistical information from the video game to a local client component, such as a web interface. The statistical information provided by the local server component may be included in one or more visual display items that are generated by the client device. The visual display items may be included in the video that is captured and transmitted by the client device, thereby potentially providing live streaming statistical information to spectators of the video game.

Techniques for improving a user video game experience are described. In an example, a computer system receives event data from a plurality of user devices. Each event data includes an identifier of an activity in a video game and data and an identifier of a mechanic used to complete the activity. The identifiers can be predefined in program code of the video game. The identifiers data can be received based on an execution of the program code. The event data is processed to determine, for a user that has not completed the activity, a readiness of the user to perform the activity. Depending on the readiness, the activity can be suggested in a user interface element.

Techniques for improving a user video game experience are described. In an example, a computer system receives event data from a plurality of user devices. Each event data includes an identifier of an activity in a video game and data and an identifier of a mechanic used to complete the activity. The identifiers can be predefined in program code of the video game. The identifiers data can be received based on an execution of the program code. The event data is processed to determine, for a user that has not completed the activity, a readiness of the user to perform the activity. Depending on the readiness, the activity can be suggested in a user interface element.