In various examples, when a user presses a button to interact with an object while playing a mobile video game, a prioritization zone around a targeting reticle can be defined. If the user positions the prioritization zone on a group of objects, a set of prioritization rules are applied to identify high importance objects (e.g., game Champions) in the prioritization zone. Based on the prioritization rules, the system can select the identified high importance object found inside the prioritization zone that is closest to the targeting reticle. In some embodiments, the prioritization zone is activated only for a defined period of time after the user presses the attack button. If the user releases the attack button during the defined period of time, the system can identify any of the objects in the prioritization zone and select a high importance object to interact with (e.g., launch an attack).

A first image related to a progress of a game is displayed on a display unit, an UI (User Interface) image receiving a first input operation related to a result of the game is displayed on the display unit in a manner of being superimposed on the first image, and the UI image is deleted by receiving a second input operation from the user even when the first input operation is not yet received.

A timer period is set on the basis of a user input, and counting processing of counting a time is executed during the timer period. During the timer period, game processing including control of a virtual object is executed. A count image indicating a state of the counting and a game image by the game processing are outputted to a display unit. Here, during the game processing, the control of the virtual object is switched between manual control based on a user input and automatic control that is not based on the user input.

Methods and systems for presenting an image of a user interacting with a video game includes providing images of a virtual reality (VR) scene of the video game for rendering on a display screen of a head mounted display (HMD). The images of the VR scene are generated as part of game play of the video game. An input provided at a user interface on the HMD received during game play is used to initiate a signal to pause the video game and to generate an activation signal to activate an image capturing device. The activation signal causes the image capturing device to capture an image of the user interacting in a physical space. The image of the user captured by the image capturing device during game play is associated with a portion of the video game that corresponds with a time when the image of the user was captured. The association causes the image of the user to be transmitted to the HMD for rendering on the display screen of the HMD.

Methods and systems for presenting an image of a user interacting with a video game includes providing images of a virtual reality (VR) scene of the video game for rendering on a display screen of a head mounted display (HMD). The images of the VR scene are generated as part of game play of the video game. An input provided at a user interface on the HMD received during game play is used to initiate a signal to pause the video game and to generate an activation signal to activate an image capturing device. The activation signal causes the image capturing device to capture an image of the user interacting in a physical space. The image of the user captured by the image capturing device during game play is associated with a portion of the video game that corresponds with a time when the image of the user was captured. The association causes the image of the user to be transmitted to the HMD for rendering on the display screen of the HMD.

A method is disclosed including setting, at a server, a server VSYNC signal to a server VSYNC frequency. The server VSYNC signal corresponding to generation of video frames during frame periods for the server VSYNC frequency. The method including setting, at a client, a client VSYNC signal to a client VSYNC frequency. The method including sending compressed video frames from the server to the client over a network using the server VSYNC signal, wherein the compressed video frames are based on the generated video frames. The method including decoding and displaying, at the client, the compressed video frames. The method including analyzing the timing of one or more client operations to adjust the relative timing between the server VSYNC signal and the client VSYNC signal, as the client receives the compressed video frames.

A method is disclosed including setting, at a server, a server VSYNC signal to a server VSYNC frequency. The server VSYNC signal corresponding to generation of video frames during frame periods for the server VSYNC frequency. The method including setting, at a client, a client VSYNC signal to a client VSYNC frequency. The method including sending compressed video frames from the server to the client over a network using the server VSYNC signal, wherein the compressed video frames are based on the generated video frames. The method including decoding and displaying, at the client, the compressed video frames. The method including analyzing the timing of one or more client operations to adjust the relative timing between the server VSYNC signal and the client VSYNC signal, as the client receives the compressed video frames.

In various examples, recordings of gameplay sessions are enhanced by the application of special effects to relatively high(er) and/or low(er) interest durations of the gameplay sessions. Durations of relatively high(er) or low(er) predicted interest in a gameplay session are identified, for instance, based upon level of activity engaged in by a gamer during a particular gameplay session duration. Once identified, different variations of video characteristic(s) are applied to at least a portion of the identified durations for implementation during playback. The recordings may be generated and/or played back in real-time with a live gameplay session, or after completion of the gameplay session. Further, video data of the recordings themselves may be modified to include the special effects and/or indications of the durations and/or variations may be included in metadata and used for playback.

A game that receives information about sleep of users maintains enjoyment of the game without placing an excessive load on a server. The game includes receiving an operation input from a user; setting a first time at which a game is to progress and making a predetermined notification at the first time when the operation input is not received before the first time arrives; changing a state of the notification based on the operation input of the user and accessing a server to progress the game; and distributing second times at which the computers of users are to access the server to progress the game.

Technologies for providing a cognitive capacity test for autonomous driving include a compute device. The compute device includes circuitry that is configured to display content to a user, prompt a message to the user to turn user’s attention to another activity that needs situational awareness, receive a user response, and analyze the user response to determine an accuracy of the user response and a response time, wherein the accuracy and response time are indicative of a cognitive capacity of the user to assume control of an autonomous vehicle when the autonomous vehicle encounters a situation that the vehicle is unable to navigate.