Provided is a game system or the like capable of setting a game field relatively wide. This game system provides a training game that progresses through a navigation character or a waiting character that moves in accordance with a user instruction in a game field of a monitor that displays a room screen including the game field. Further, for example, the game system specifies a position relationship between a waiting position and a guide position, when the user instructs the waiting character to move from the waiting position to the guide position in the game field, and changes a moving speed of the waiting character between a normal speed and a special speed in accordance with the specified position relationship, when the waiting character moves from the waiting position to the guide position.

A computer-implemented method, non-transitory computer-readable medium and apparatus for dynamic management of formations in a video game. The method includes maintaining a virtual three-dimensional environment and causing a plurality of video game characters to travel along a path in the virtual three-dimensional environment in a formation. The formation has a formation type and the formation type is a first formation type. The method also includes moving the formation along the path. The method also includes, responsive to determining a change in characteristics of the path at a point in the virtual three-dimensional environment that is ahead of the formation, changing the formation type to a second formation type in advance of the change in characteristics of the path.

Foot-gesture-based movement control method for a game character includes a four-way movement start control process, including: determining the game character being in a non-moving state; obtaining foot tilt angles and tilt states of left and right feet of a user; determining a tilt state change of each foot of the user; and generating movement start controls in first, second, third, and fourth directions for the game character, respectively when the right foot is detected changing from a leveled state to a positively tilted state and changing from a leveled state to a negatively tilted state, the left foot is detected changing from a leveled state to a positively tilted state and changing from a leveled state to a negatively tilted state.

A procedural content generation tool operates by: generating, via image analysis, graphs of existing game content; generating a symmetrical Markov random field (SMRF) model based on the graphs; and automatically generating, via iterative artificial intelligence (AI), new game content based on the SMRF model.

In one or more embodiments, one or more systems, one or more methods, and/or one or more processes may: if historical biometric data associated with a user is available is not available, collect the historical biometric data; if the historical biometric data is available, retrieve the historical biometric data; execute an application; display at least a portion of a graphic; determine that a gaze of the user includes the at least the portion of the graphic; determine a stress index threshold associated with the user; determine a stress index associated with the user, accounting for the at least the portion of the graphic exceeding the brightness threshold; determine that the stress index has reached or exceeded the stress index threshold; provide a notification indicating that the first stress index has reached or exceeded the stress index threshold; and reduce one or more stress inducing attributes associated with the application.

In one or more embodiments, one or more systems, one or more methods, and/or one or more processes may: if historical biometric data associated with a user is available is not available, collect the historical biometric data; if the historical biometric data is available, retrieve the historical biometric data; execute an application; display at least a portion of a graphic; determine that a gaze of the user includes the at least the portion of the graphic; determine a stress index threshold associated with the user; determine a stress index associated with the user, accounting for the at least the portion of the graphic exceeding the brightness threshold; determine that the stress index has reached or exceeded the stress index threshold; provide a notification indicating that the first stress index has reached or exceeded the stress index threshold; and reduce one or more stress inducing attributes associated with the application.

Systems and methods for determining excessive motions or strained positions based on inputs associated with gameplay of game titles. A game intervention server may evaluate, based on learning models, posture, and physical motions of players for repetitive, unbalanced, or excessive motions, as well as gameplay quality patterns, and compare to thresholds for identifying unhealthy conditions. The game intervention server may make recommendations regarding breaks, stretches, warm-up/cool-down, curbing extended periods of play, etc. Notifications may be overlaid on screen with option to pause play without exiting game session. In-game events and requirements may also be adjusted based on learned insights to avoid excessive movement or counteract unbalanced movement.

Systems and methods for determining excessive motions or strained positions based on inputs associated with gameplay of game titles. A game intervention server may evaluate, based on learning models, posture, and physical motions of players for repetitive, unbalanced, or excessive motions, as well as gameplay quality patterns, and compare to thresholds for identifying unhealthy conditions. The game intervention server may make recommendations regarding breaks, stretches, warm-up/cool-down, curbing extended periods of play, etc. Notifications may be overlaid on screen with option to pause play without exiting game session. In-game events and requirements may also be adjusted based on learned insights to avoid excessive movement or counteract unbalanced movement.

A virtual object control method includes obtaining a panel presentation instruction generated through triggering on a user interface (UI) and presenting an interaction control panel on the UI in response to the panel presentation instruction. When an interaction button or a movement on the interaction control panel is triggered, and the interaction button is associated with an object selection panel, the interaction control panel is replaced with the object selection panel in the UI. A to-be-controlled virtual object is selected through the object selection panel and the selected virtual object to perform interaction is controlled according to an interaction corresponding to the interaction button.

A virtual object control method includes obtaining a panel presentation instruction generated through triggering on a user interface (UI) and presenting an interaction control panel on the UI in response to the panel presentation instruction. When an interaction button or a movement on the interaction control panel is triggered, and the interaction button is associated with an object selection panel, the interaction control panel is replaced with the object selection panel in the UI. A to-be-controlled virtual object is selected through the object selection panel and the selected virtual object to perform interaction is controlled according to an interaction corresponding to the interaction button.