A display apparatus according to an embodiment of the present disclosure includes: a thin plate-like display cell that displays an image; M exciters that are disposed on a back surface side of the display cell, and vibrate the display cell; and a driving section that drives the display cell and the M exciters.

A sound effect controlling method and a sound outputting device with dynamic gain adjustment are disclosed. The sound effect controlling method includes the following steps. An original left sound signal and an original right sound signal are transformed to a virtual center sound signal, a virtual left sound signal, a virtual left surrounding sound signal, a virtual right surrounding sound signal and a virtual right sound signal according to a center gain, a left gain, a left surrounding gain, a right surrounding gain and a right gain, which are calculated according to a rotation angle and a dual sound relationship. An updated left sound signal and an updated right sound signal are obtained according to the virtual center sound signal, the virtual left sound signal, the virtual left surrounding sound signal, the virtual right surrounding sound signal and the virtual right sound signal.

Disclosed is an audio signal processing method including: receiving a stereo signal; transforming the stereo signal into a frequency-domain signal; rendering the first signal based on a first ipsilateral filter coefficient; generating a frontal ipsilateral signal relating to the frequency-domain signal; rendering the second signal based on a second ipsilateral filter coefficient; generating a side ipsilateral signal relating to the frequency-domain signal; rendering the second signal based on a contralateral filter coefficient; generating a side contralateral signal relating to the frequency-domain signal; transforming an ipsilateral signal, generated by mixing the frontal ipsilateral signal and the side ipsilateral signal, and the side contralateral signal into a time-domain ipsilateral signal and a time-domain contralateral signal, which are time-domain signals, respectively; and generating a binaural signal by mixing the time-domain ipsilateral signal and the time-domain contralateral signal.

Disclosed is a data processing method, comprising: acquiring space information of audio acquisition devices of an acquisition device, an acquisition space corresponding to the acquisition device being formed into a geometry, the spatial orientation deployed by video acquisition devices of the acquisition device covering the entire geometry, and the setting orientation of each video acquisition device being correspondingly provided with N audio acquisition devices, wherein N is a positive integer; regarding the N audio acquisition devices provided corresponding to the setting orientation of each video acquisition device, encoding audio data acquired by the N audio acquisition devices according to the space information of the audio acquisition devices, to form M pieces of audio data, the M pieces of audio data carrying space information of audios. Embodiments of the present invention further provide an acquisition device, a data processing device, and a storage medium.

A spatialized audio presentation system selects, based on an orientation of an avatar with respect to a virtual sound source, a head-related impulse response from a library of head-related impulse responses corresponding to different potential orientations of the avatar with respect to the virtual sound source. The spatialized audio presentation system applies the selected head-related impulse response to a sound that is generated by the virtual sound source and is to be presented to a user associated with the avatar. Additionally, the spatialized audio presentation system applies an additional effect to the sound that is to be presented to the user. Corresponding methods and systems are also disclosed.

A mobile device implemented method provides audio from a virtual audio source in an augmented reality view of a scene. The method includes operations of sending scene identification data to a server storing precomputed acoustic parameters for multiple scenes, receiving precomputed acoustic parameters corresponding to the scene, aligning the view to register the audio to the augmented reality view of the scene, and rendering and playing the audio using the obtained acoustic parameters.

A mobile computing device that provides location information through directional sound is described herein. The mobile computing device includes a location detection system that provides location signals corresponding to a user location and a destination location, such as a vehicle location or a vertex of a predefined travel route, to a spatial audio generation system to define a spatial audio signal based on a direction from the user location to the destination location. The spatial audio signal is provided to an audio device of the mobile computing device that outputs the spatial audio signal as directional sound having a locus at the destination location.

Embodiments are described for rendering spatial audio content through a system that is configured to reflect audio off of one or more surfaces of a listening environment. The system includes an array of audio drivers distributed around a room, wherein at least one driver of the array of drivers is configured to project sound waves toward one or more surfaces of the listening environment for reflection to a listening area within the listening environment and a renderer configured to receive and process audio streams and one or more metadata sets that are associated with each of the audio streams and that specify a playback location in the listening environment.

Embodiments are described for an adaptive audio system that processes audio data comprising a number of independent monophonic audio streams. One or more of the streams has associated with it metadata that specifies whether the stream is a channel-based or object-based stream. Channel-based streams have rendering information encoded by means of channel name; and the object-based streams have location information encoded through location expressions encoded in the associated metadata. A codec packages the independent audio streams into a single serial bitstream that contains all of the audio data. This configuration allows for the sound to be rendered according to an allocentric frame of reference, in which the rendering location of a sound is based on the characteristics of the playback environment (e.g., room size, shape, etc.) to correspond to the mixer's intent. The object position metadata contains the appropriate allocentric frame of reference information required to play the sound correctly using the available speaker positions in a room that is set up to play the adaptive audio content.

An acoustic processing device including a memory storing instructions and a processor that implements the stored instructions to execute a plurality of tasks, the tasks including: an analyzing task that analyzes an input signal; a determining task that determines an acoustic effect to be applied to the input signal, from among a first acoustic effect of virtual surround and a second acoustic effect of virtual surround different from the first acoustic effect, based on a result of the analyzing task; and an acoustic effect applying task that applies the acoustic effect determined by the determining task to the input signal.