An electronic device 10 includes: a setting unit 231 that sets an association between a first game medium that is selected by a player and that serves as an operation target in the game and a second game medium that is selected by the player; a skip-processing-procedure deciding unit 232 that decides, on the basis of priorities respectively associated with skill-related processing procedures of the first game medium and the second game medium, the skill-related processing procedure that becomes a skip target; and a skill-processing-procedure executing unit 233 that executes skill processing procedures respectively associated with the first game medium and the second game medium on the basis of a player input, wherein the skill-processing-procedure executing unit 233 skips the decided skill-related processing procedure when the skill processing procedures associated with the first game medium and the second game medium are executed.

Projectile data associated with a projectile launched by a player in a live-action sequence may be used to render an accurate graphical representation of the projectile (and its trajectory) within a virtual reality environment, e.g., for use in a virtual reality game or similar. For example, certain implementations described herein include the use of projectile data characterizing the path of a cricket ball bowled by a player (e.g., the “bowler”) in a live-action cricket match for recreating the same (or substantially the same) path in a virtual reality cricket game. To this end, the present disclosure includes techniques for transforming projectile data for use in a virtual reality environment, creating realistic projectile movement in a virtual reality setting, and determining and recreating post-bounce behavior of a projectile for virtual representation of a bounced projectile.

Projectile data associated with a projectile launched by a player in a live-action sequence may be used to render an accurate graphical representation of the projectile (and its trajectory) within a virtual reality environment, e.g., for use in a virtual reality game or similar. For example, certain implementations described herein include the use of projectile data characterizing the path of a cricket ball bowled by a player (e.g., the “bowler”) in a live-action cricket match for recreating the same (or substantially the same) path in a virtual reality cricket game. To this end, the present disclosure includes techniques for transforming projectile data for use in a virtual reality environment, creating realistic projectile movement in a virtual reality setting, and determining and recreating post-bounce behavior of a projectile for virtual representation of a bounced projectile.

In some implementations, a method of improved pathfinding is performed at a virtual agent operating system including non-transitory memory and one or more processors coupled with the non-transitory memory. The method includes: determining an initial path for a virtual agent to a target destination based at least in part on a navigation mesh of an XR environment; actuating locomotive elements of the virtual agent in order to move the virtual agent according to the initial path; while moving according to the initial path, detecting a node of a navigation graph; in response to detecting the node of the navigation graph: obtaining navigation information from the node of the navigation graph; and determining an updated path from the node to the target destination based at least in part on the navigation mesh and the navigation information; and actuating the locomotive elements of the virtual agent according to the updated path.

A non-transitory computer-readable medium storing a game program causing a processor of a terminal device used by a user to execute: displaying an indication object 50 including an indication relating to a shot of a ball 31; receiving a first input operation performed by the user on a display screen; determining a position of a moving object 40 based on the first input operation; moving the moving object 40 toward the indication object 50 when the first input operation is released; and executing the shot in accordance with a release position of the first input operation and the indication determined by a positional relationship between the indication object 50 and the moving object after movement.

A virtual golf course generation system of the present embodiment includes: a field template generation unit for generating a field template including information on a terrain and an altitude of a specific location and information on an object, by using a result classified or extracted from different map data so as to generate a virtual golf course; a 3D green terrain generation unit for generating a 3D green terrain by using a three-dimensional mesh generated using terrains and altitudes of a green and a green bunker of the actual golf course to be displayed on the virtual golf course; and a matching unit for matching the generated 3D green terrain with the field template to generate the virtual golf course.

An endpoint system including one or more computing devices presents an object in a virtual environment (e.g., a shared virtual environment); receives gaze input corresponding to a gaze of a user of the endpoint system; calculates a gaze vector based on the gaze input; receives motion input corresponding to an action of the user; determines a path adjustment (e.g., by changing motion parameters such as trajectory and velocity) for the object based at least in part on the gaze vector and the motion input; and simulates motion of the object within the virtual environment based at least in part on the path adjustment. The object may be presented as being thrown by an avatar, with a flight path based on the path adjustment. The gaze vector may be based on head orientation information, eye tracking information, or some combination of these or other gaze information.

An endpoint system including one or more computing devices presents an object in a virtual environment (e.g., a shared virtual environment); receives gaze input corresponding to a gaze of a user of the endpoint system; calculates a gaze vector based on the gaze input; receives motion input corresponding to an action of the user; determines a path adjustment (e.g., by changing motion parameters such as trajectory and velocity) for the object based at least in part on the gaze vector and the motion input; and simulates motion of the object within the virtual environment based at least in part on the path adjustment. The object may be presented as being thrown by an avatar, with a flight path based on the path adjustment. The gaze vector may be based on head orientation information, eye tracking information, or some combination of these or other gaze information.

An information processing method and apparatus in a Virtual Reality (VR) game, and a processor are provided. The method includes that: a first move operation of a VR controller in a real environment is acquired; a move of a virtual object in a VR game scene is controlled according to the first move operation, and a calculation factor is calculated according to the first move operation; and when the move of the virtual object in the VR game scene satisfies a preset attack damage trigger condition, damage to an attack target in the VR game scene is calculated according to the calculation factor. The present disclosure solves technical problems in the related art that an operation mode of swinging a weapon to launch an attack in a VR game scene is easy to cause fatigue of a game player and a calculation mode of damage lacks accuracy.

An information processing method and apparatus in a Virtual Reality (VR) game, and a processor are provided. The method includes that: a first move operation of a VR controller in a real environment is acquired; a move of a virtual object in a VR game scene is controlled according to the first move operation, and a calculation factor is calculated according to the first move operation; and when the move of the virtual object in the VR game scene satisfies a preset attack damage trigger condition, damage to an attack target in the VR game scene is calculated according to the calculation factor. The present disclosure solves technical problems in the related art that an operation mode of swinging a weapon to launch an attack in a VR game scene is easy to cause fatigue of a game player and a calculation mode of damage lacks accuracy.