The present specification describes methods and systems for modifying a media, such as Virtual Reality, Augmented Reality, or Mixed Reality (VR/AR/MxR) media based on a vision profile and a target application. In embodiments of the specification, a Sensory Data Exchange (SDE) is created that enables identification of various vision profiles for users and user groups. The SDE may be utilized to modify one or more media in accordance with each type of user and/or user group.

A control method includes obtaining feature data using at least one sensor, the feature data being acquired by the terminal using the at least one sensor, generating an action instruction based on the feature data and a decision-making mechanism of the terminal, and executing the action instruction. In this application, various aspects of feature data are acquired using a plurality of sensors, data analysis is performed on the feature data, and a corresponding action instruction is then generated based on a corresponding decision-making mechanism to implement interactive control.

According to one aspect of the present invention, a virtual reality control system for providing a chemical accident response training content includes a sensor detecting a light signal, a display displaying an image, at least one controller controlling the display, and a simulator displayed as a valve in the image, wherein the controller is configured to acquire first position data related to the user and second position data related to the simulator based on the light signal, acquire first virtual position data indicating a character corresponding to the user and acquire second virtual position data indicating the valve, and display the character and the valve on the display and display a gas within a predetermined distance from the valve, wherein at least a portion of the gas is not displayed when the character moves while at least a portion of the character is in contact with the valve.

According to one aspect of the present invention, a virtual reality control system for providing a chemical accident response training content includes a sensor detecting a light signal, a display displaying an image, at least one controller controlling the display, and a simulator displayed as a valve in the image, wherein the controller is configured to acquire first position data related to the user and second position data related to the simulator based on the light signal, acquire first virtual position data indicating a character corresponding to the user and acquire second virtual position data indicating the valve, and display the character and the valve on the display and display a gas within a predetermined distance from the valve, wherein at least a portion of the gas is not displayed when the character moves while at least a portion of the character is in contact with the valve.

An interactive energy effect system that includes one or more sensors configured to generate a signal indicative of a position of a user-associated object in the system. The interactive energy effect system also includes a system controller that receives the signal and generates a first and second set of instructions based on the signal. The system controller transmits the first instructions to an energy emission system to cause the energy emission system to reposition and activate an energy emitter. The system controller transmits the second instructions to a multi-layer display system to cause the multi-layer display system to move towards or away from the user-associated object.

A rhythm-based video game (“game”) is disclosed. In the game, a player slashes blocks representing musical beats using a pair of energy blades resembling a lightsaber. A gaming console renders multiple digital objects, e.g., digital blocks, digital mines and digital obstacles, that are approaching a player in a virtual space. The gaming console also renders a digital representation of an instrument, e.g., a lightsaber (“digital saber”), using which the player slashes, cuts or otherwise interacts with the digital blocks to cause a digital collision between the digital saber and the digital blocks. The player can score by slashing the digital blocks, not hitting the digital mines and avoiding the digital obstacles. The game presents the player with a stream of approaching digital objects in synchronization with music, e.g., a song's beats, being played in the game. The pace at which the digital blocks approach the player increases with the beats.

A rhythm-based video game (“game”) is disclosed. In the game, a player slashes blocks representing musical beats using a pair of energy blades resembling a lightsaber. A gaming console renders multiple digital objects, e.g., digital blocks, digital mines and digital obstacles, that are approaching a player in a virtual space. The gaming console also renders a digital representation of an instrument, e.g., a lightsaber (“digital saber”), using which the player slashes, cuts or otherwise interacts with the digital blocks to cause a digital collision between the digital saber and the digital blocks. The player can score by slashing the digital blocks, not hitting the digital mines and avoiding the digital obstacles. The game presents the player with a stream of approaching digital objects in synchronization with music, e.g., a song's beats, being played in the game. The pace at which the digital blocks approach the player increases with the beats.

An extended-reality projectile-firing gaming system includes a projectile-firing device, a battlefield object configured to detect impact of projectiles thereon, a network configured to provide communication and control connectivity in accordance with at least one protocol to the projectile-firing device and the wearable device, and an extended-reality gaming application. The application controls the projectile-firing device and the wearable device, receives projectile-firing device data from the projectile-firing device, receives battlefield object data from a battlefield object, the battlefield object data indicating that an impact occurred on the battlefield object, and the time the battlefield object was impacted, and updates gaming metric data to indicate a successful impact of the fired projectile on the battlefield object and a successful hit by the projectile-firing device on the battlefield object when the time the impact occurred on the battlefield object and the time the projectile was fired occur within a predetermined time period.

An extended-reality projectile-firing gaming system includes a projectile-firing device, a battlefield object configured to detect impact of projectiles thereon, a network configured to provide communication and control connectivity in accordance with at least one protocol to the projectile-firing device and the wearable device, and an extended-reality gaming application. The application controls the projectile-firing device and the wearable device, receives projectile-firing device data from the projectile-firing device, receives battlefield object data from a battlefield object, the battlefield object data indicating that an impact occurred on the battlefield object, and the time the battlefield object was impacted, and updates gaming metric data to indicate a successful impact of the fired projectile on the battlefield object and a successful hit by the projectile-firing device on the battlefield object when the time the impact occurred on the battlefield object and the time the projectile was fired occur within a predetermined time period.

A system and method for targeted neurological treatment using brainwave entrainment therapy with passive treatment that allows for targeted treatment of particular areas of the brain, particular neurological functions, particular neurological states, and combinations of areas, functions, and states. The system and method receive gait parameters for an individual and compare those against a database of historical gait data to determine if an onset neurodegenerative condition is present, and applies a brainwave entrainment therapy responsive to the determination of the condition. The system and method receive a neurological assessment identifying areas of the brain or neurological functions to be treated, select one or more treatment modalities and frequencies, select a treatment regimen, and apply brainwave entrainment using a treatment regimen while the subject engages in dual-task activities selected to stimulate the areas of the brain, neurological functions, or neurological states to be treated, enhanced, or altered.