A virtual surround sound production circuit includes: a subtraction unit configured to perform subtraction operation on first and second signals to output a third signal; a first addition unit configured to perform addition operation on the first and second signals to output a center channel signal; a surround sound adjustment unit configured to adjust the third signal or another third signal that has undergone frequency compensation to output a fourth signal; a center compensation unit configured to adjust the center channel signal to output a fifth signal; a second addition unit configured to perform addition operation on the first, fourth and fifth signals to output a first output signal; a phase inverter unit configured to perform phase inversion on the fourth signal to generate a phase-inverted signal; and a third addition unit configured to perform addition operation on the second, fifth and phase-inverted signals to output a second output signal.

The present invention provides a method for processing audio data, comprising the steps of providing input audio data containing a mixture of audio data including first audio data of a first musical timbre and second audio data of a second musical timbre different from said first musical timbre, decomposing the input audio data to provide decomposed data representative of the first audio data, transforming the decomposed data to obtain third audio data.

An audio output method, an electronic device and a computer-readable storage medium are provided. The method includes: detecting a current connection state of the electronic device with peripheral audio output devices; acquiring, in response to the electronic device is detected as being connected to at least two peripheral audio output devices, an output audio type configured for each of the at least two peripheral audio output devices; acquiring an audio type of an audio; determining, based on the audio type of the audio and the output audio type configured for each of the at least two peripheral audio output devices, a target peripheral audio output device from the at least two peripheral audio output devices; and outputting the audio through the target peripheral audio output device. Flexibility of audio output is improved.

A method for Bluetooth audio multi-streaming by a first electronic device includes establishing a Broadcast Isochronous Group (BIG) with second electronic devices, broadcasting a first audio to the second electronic devices over the BIG, detecting an audio event at the first electronic device while broadcasting the first audio to the second electronic devices, determining one or more primary electronic devices of the second electronic devices and one or more secondary electronic devices of the second electronic devices, and continuing to broadcast the first audio over the BIG to the one or more secondary electronic devices and concurrently unicasting a second audio that corresponds to the audio event over a Connected Isochronous Group (CIG) connection to the one or more primary electronic devices.

A voice aware audio system and a method for a user wearing a headset to be aware of an outer sound environment while listening to music or any other audio source. An adjustable sound awareness zone gives the user the flexibility to avoid hearing far distant voices. The outer sound can be analyzed in a frequency domain to select an oscillating frequency candidate and in a time domain to determine if the oscillating frequency candidate is the signal of interest. If the signal directed to the outer sound is determined to be a signal of interest the outer sound is mixed with audio from the audio source.

In one aspect of the present disclosure, method includes: receiving neural data responsive to a listener's auditory attention; receiving an acoustic signal responsive to a plurality of acoustic sources; for each of the plurality of acoustic sources: generating, from the received acoustic signal, audio data comprising one or more features of the acoustic source, forming combined data representative of the neural data and the audio data, and providing the combined data to a classification network configured to calculate a similarity score between the neural data and the acoustic source using one or more similarity metrics; and using the similarity scores calculated for each of the acoustic sources to identify, from the plurality of acoustic sources, an acoustic source associated with the listener's auditory attention.

A remote control with a microphone subsystem comprising a pair of internal microphones is shown and described. When connected to a remote-control base station that is itself connected to an external power source, the microphone subsystem is continuously energized by the external power source, and the pair of internal microphones operate as far field microphones that receive oral commands uttered by a user from a distance. When the remote control is removed from the base, the microphone subsystem is configured for selective connection to an internal power source by actuating a user control on the remote control. In the external power source mode, signals from both microphones are digitally processed to provide a far-field microphone array with beam forming. In the direct current mode, only one microphone's signals are digitally processed as a simple monaural signal (or they are not digitally processed). The remote control also includes a video camera capable of capturing video image data of the user and transmitting it to an associated television for facial recognition of the user.

A head-worn audio device is provided with a circuit for voice signal enhancement. The circuit comprises at least a plurality of microphones, arranged at predefined positions, where each microphone provides a microphone signal. The circuit further comprises a directivity pre-processor and a blind source separation processor. The directivity pre-processor is connected with the plurality of microphones to receive the microphone signals and being configured to provide at least a voice signal and a noise signal. Directivity pre-processing increases the mutual independence of the signals provided to the blind source separation processor and thus improves processing by blind source separation. The blind source separation processor receives at least the voice signal and the noise signal, and is configured to conduct blind source separation on at least the voice signal and the noise signal to provide at least an enhanced voice signal with reduced noise components.

A computing device is configured to perform functions comprising: receiving via a network microphone device of a media playback system, a voice command detected by at least one microphone of the network microphone device, wherein the media playback system comprises a plurality of zones, and the network microphone device may be a member of a default playback zone. The computing device may be further configured to perform functions comprising: dynamically selecting an audio response zone from the plurality of zones to play an audio response to the voice input and foregoing selection of the default playback zone. The selected zone may comprise a playback device, and the dynamically selecting may comprise determining that the network microphone device is paired with the playback device. The computing device may cause the playback device of the selected zone to play the audio response.

A mode control method includes determining, by a terminal device based on a scene type of an external environment, that a processing mode used by a headset is a target mode. The target mode is one of a plurality of processing modes supported by the headset, where different processing modes correspond to different scene types, and the processing modes supported by the headset include at least two of the following modes: an active noise control (ANC) mode, a hear-through (HT) mode, or an augmented hearing (AH) mode. Processing intensity in the target mode is automatically adjusted based on an event in a current external environment. The terminal device further provides a control interface for the headset to provide selection controls for the user to select a processing mode and processing intensity. The user controls a processing mode and processing intensity of the headset based on a requirement.