A method for dynamically modifying audio playback of a video game is provided. The method includes ascertaining a game music data associated with the video game. The game music data may include a plurality of game soundtracks classified according to predetermined criteria. The method may include collecting feedback over a period of time while the user is playing the video game. The method may continue with determining, based on the feedback, one or more replacement soundtracks based on criteria associated with the one or more replacement soundtracks. The method may further include dynamically modifying the game music data while the user is playing the video game by replacing at least one of the plurality of game soundtracks with the one or more replacement soundtracks to obtain modified game music data. The modified game music data may be provided to the user while the user is playing the video game.

Incorporating player-generated audio in an electronic game is disclosed. Incorporation may include receiving an audio clip from art electronic game player, applying a modification to the audio clip to generate a chant, associating the chant to the execution of an event in the electronic game, retrieving the chant when the event in the electronic game is executed, and initiating the play of the chant upon execution of the event in the electronic game.

A data communication restricted content providing device executes a program of game content, accepts operation input for the game content, controls the game content in accordance with operation input, generates, based on information of a changed progress condition of the game content, audio data indicating the progress condition, and plays back the audio data. An information processing device acquires an audio signal played back by the content providing device, extracts information of the progress condition from the audio signal, and outputs, to an external device, information of the progress condition.

Methods of enhancing a sensory experience to simulate a live event are provided. One includes providing an audible signal representing sound information; generating a vibration signal based on the audible signal and enhanced information that would be present at the live event; and providing the vibration signal to at least one vibration device for stimulating nerve receptors in a foot area, the vibration signal synchronized with the audible signal to produce a perception in the brain of being present at the live event. Another method includes generating a vibration signal representing vibrations including tactile vibrations for stimulating nerve receptors in a foot to simulate being present at a live event, and vibrations based on reproduced sound information; and providing the signal to at least one vibration device for delivering the vibrations to the feet, the tactile vibrations based on enhanced information different from the sound information and including non-audible elements.

Methods and systems for presenting an object on to a screen of a head mounted display (HMD) include receiving an image of a real-world environment in proximity of a user wearing the HMD. The image is received from one or more forward facing cameras of the HMD and processed for rendering on a screen of the HMD by a processor within the HMD. A gaze direction of the user wearing the HMD, is detected using one or more gaze detecting cameras of the HMD that are directed toward one or each eye of the user. Images captured by the forward facing cameras are analyzed to identify an object captured in the real-world environment that is in line with the gaze direction of the user, wherein the image of the object is rendered at a first virtual distance that causes the object to appear out-of-focus when presented to the user. A signal is generated to adjust a zoom factor for lens of the one or more forward facing cameras so as to cause the object to be brought into focus. The adjustment of the zoom factor causes the image of the object to be presented on the screen of the HMD at a second virtual distance that allows the object to be discernible by the user.

Methods and systems are provided for augmenting voice output of a virtual character in an augmented reality (AR) scene. The method includes examining, by a server, the AR scene, said AR scene includes a real-world space and the virtual character overlaid into the real-world space at a location, the real-world space includes a plurality of real-world objects present in the real-world space. The method includes processing, by the server, to identify an acoustics profile associated with the real-world space, said acoustics profile including reflective sound and absorbed sound associated with real-world objects proximate to the location of the virtual character. The method includes processing, by the server, the voice output by the virtual character while interacting in the AR scene; the processing is configured to augment the voice output based on the acoustics profile of the real-world space, the augmented voice output being audible by an AR user viewing the virtual character in the real-world space. In this way, when the voice output of the virtual character is augmented, the augmented voice output may sound more realistic to the AR user as if the virtual character is physically present in the same real-world space as the AR user.

A system that incorporates teachings of the present disclosure may include, for example, a computing device having a controller to modify sound produced by a gaming application according to an otological profile of a user. Additional embodiments are disclosed.

A method for determining an environment in which a user is located is described. The method includes receiving a plurality of sets of audio data based on sounds emitted in a plurality of environments. Each of the plurality of environments has a different combination of objects. The method further includes receiving input data regarding the plurality of environments, and training an artificial intelligence (AI) model based on the plurality of sets of audio data and the input data. The method includes applying the AI model to audio data captured from an environment surrounding the first user to determine a type of the environment.

Disclosed is a system for increasing attention ability of a user using a gameplay. The system may include a display device configured to display a moving image comprising an object, a cursor and a points counter. Further, the system may include an audio device configured to produce acoustic waves based on a sound data associated with a level. Further, the system may include an input device configured to receive a spatial input data. Further, the system may include a processing device communicatively coupled to each of the display device, the audio device and the input device. Further, the system may include a storage device communicatively coupled to the processing device. Further, the storage device may be configured to store digital data corresponding to an object, a cursor, a current cursor location, a previous cursor location, a geometric shape and the sound data in association with the multiple level indicators.

A system that incorporates teachings of the present disclosure may include, for example, an audio control apparatus having a game audio port for receiving a gaming audio signal generated by a gaming application, a chat port for receiving a chat signal comprising audio information generated by at least one gamer, and an audio system coupled to the game audio port and the chat port. The audio system can be operable to detect an energy level in the chat signal that exceeds a threshold, reduce a magnitude of the gaming audio signal to a desired audio energy level responsive to the aforementioned detection, generate a mixed audio signal comprising a combination of the gaming audio signal having the reduced magnitude and the chat signal, and transmit the mixed audio signal to a listening apparatus. Additional embodiments are disclosed.