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.

A system that incorporates the subject disclosure may include, for example, a gaming system that cooperates with a graphical user interface to enable user modification and enhancement of one or more audio streams associated with the gaming system. In embodiments, the audio streams may include a game audio stream, a chat audio stream of conversation among players of a video game, and a microphone audio stream of a player of the video game. Additional embodiments are disclosed.

Methods and systems for presenting an object on 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.

A video game controller can automatically operate as a video game controller with audio capability and a video game controller without audio capability based upon a signal received via a switch in communication with an audio jack of the video game controller when a headset is coupled to the audio jack. Connection of the headset to the controller automatically causes video game audio to be communicated from the video game console to the headset via the controller. The video game audio is communicated at a default volume level to the headset upon coupling of the headset to the video game controller. The volume level of the audio communicated to the headset can be adjustable up or down via a directional pad of the video game controller while an audio control button on the video game controller is pressed.

A method of generating audio assets, comprising the steps of: receiving a plurality of input audio assets, converting each input audio asset into an input graphical representation, generating an input multi-channel image by stacking each input graphical representation in a separate channel of the image, feeding the input multi-channel image into a generative model to train the generative model and generate one or more output multi-channel images, each output multi-channel image comprising an output graphical representation, extracting the output graphical representations from each output multi-channel image and converting each output graphical representation into an output audio asset.

A method of generating audio assets, comprising the steps of: receiving an input multi-layered audio asset comprising a plurality of audio layers, generating an input multi-channel image, wherein each channel of the input multi-channel image comprises an input image representative of one of the audio layers, training a generative model on the input multi-channel image and implementing the trained generative model to generate an output multi-channel image, wherein each channel of the output multi-channel image comprises an output image representative of an output audio layer, and generating an output multi-layered audio asset based on a combination of output audio layers derived from the output images.

A game based on a game program includes a game configured to progress by moving a location of a terminal apparatus possessed by a user, the game program causing a processor to perform enabling the game to progress by using predetermined moving means to move the terminal apparatus by the user who possesses the terminal apparatus, and announcing information for the user using a display unit in a non specific mode other than during a game progressing by using the predetermined moving means to move the location of the terminal apparatus, and announcing the information for the user using an output unit other than the display unit in a specific mode during the game progressing by using the predetermined moving means to move the location of the terminal apparatus.

This application discloses a method and apparatus for determining characteristics of a sound source. The method may include: acquiring a first position of a first virtual role controlled by an application client in a virtual scene; detecting, in a sound source detection area associated with the first position, a second position of a sound source virtual object in the virtual scene; determining transparency of a position mark that matches the sound source virtual object, according to a sound source distance between the first position and the second position, the position mark identifying the second position of the sound source virtual object; and displaying, on an interaction interface of the application client, the position mark of the sound source virtual object according to the transparency.

A method for emulation of graphical parameters during a play of a legacy game is described. The method includes receiving a user input from a hand-held controller and determining whether one or more basic blocks of code for servicing the user input are stored in a cache. The method further includes compiling the one or more basic blocks of code from one or more emulated processing unit (PU) code instructions upon determining that the one or more basic blocks are not stored in the cache. The method includes executing the one or more basic blocks of code to generate one or more legacy graphical parameters. The method includes emulating the one or more legacy graphical parameters to generate one or more image frames having one or more updated graphical parameters for display of one or more images of the legacy game on a display device.

The game device includes a reception unit that is configured to receive instruction information created when a user performs an operation on an input device triggered by a sound output while a game progresses and a derivation unit that is configured to start measuring the degree of fatigue on the basis of the instruction information received by the reception unit and derive the degree of fatigue of the user on the basis of an operation performed by the user during the started measurement of the degree of fatigue.