In various embodiments, an electronic device comprises: a wireless communication module; a memory storing a priority of a plurality of external electronic devices; an output module; and a processor operatively connected to the wireless communication module, the memory, and the output module, wherein the processor is configured to: control the wireless communication module to establish a first wireless communication channel with a first external electronic device; control the wireless communication module to establish a second wireless communication channel with a second external electronic device; control the output module to output first audio data received through the first wireless communication channel; identify a priority of the first external electronic device and a priority of the second external electronic device when receiving second audio data through the second wireless communication channel while outputting the first audio data; identify a type of the first audio data and a type of the second audio data; adjust an output parameter of the first audio data and an output parameter of the second audio data based on the priority of the first external electronic device, the priority of the second external electronic device, the type of the first audio data, and the type of the second audio data; and output the first audio data using the adjusted output parameter of the first audio data and the second audio data using the adjusted output parameter of the second audio data through the output module. Various other embodiments are possible.

An audio apparatus comprises a receiver (201) receiving data describing an audio scene. The data comprises audio data for a set of audio elements corresponding to audio sources in the scene and further includes metadata comprising at least an audio rendering property indicator for a first audio element of the set of audio elements. A first renderer (205) renders audio elements by generating a first set of audio signals for a set of loudspeakers and a second renderer (207) renders audio elements by generating a second set of audio signals for a headphone. Further, a selector (209) is arranged to select between the first renderer and the second renderer for rendering of at least a first part of the first audio element in response to the first audio rendering property indicator. The approach may for example provide improved virtual reality experiences using loudspeakers and headphone hybrid rendering.

A headset includes a wearable body, first and second earphones extending from the wearable body, controls for controlling an external communication/multimedia device wirelessly, a microphone for picking up vocal data from a user of the headset system and a signal processing unit. The signal processing unit includes circuitry for processing the vocal data into a distinctly audible vocal feedback signal, circuitry for enhancing the vocal feedback signal thereby producing an enhanced vocal feedback signal and circuitry for mixing the enhanced vocal feedback signal with audio signals originating from the external communication/multimedia device, thereby producing a mixed output signal and then sending the mixed output signal to the user via the earphones. The external communication/multimedia device comprises a vocal command application and the headset further comprises a vocal command control for sending vocal commands to the external communication/multimedia device and to the vocal command application.

This disclosure describes techniques for detecting voice commands from a user of an ear-based device. The ear-based device may include an in-ear facing microphone to capture sound emitted in an ear of the user, and an exterior facing microphone to capture sound emitted in an exterior environment of the user. The in-ear microphone may generate an inner audio signal representing the sound emitted in the ear, and the exterior microphone may generate an outer audio signal representing sound from the exterior environment. The ear-based device may compute a ratio of a power of the inner audio signal to the outer audio signal and may compare this ratio to a threshold. If the ratio is larger than the threshold, the ear-based device may detect the voice of the user. Further, the ear-based device may set a value of the threshold based on a level of acoustic seal of the ear-based device.

A switching device is adapted for a true diversity receiver and contains: a control switch defined between two microcontrollers of two antennas and configured to switch RF wireless microphone signals so that the two microcontrollers execute a single-receiving dual true diversity program or a dual-receiving single true diversity program. The RF wireless microphone signals are received by the two antennas and are decoded to sound signals by two digital decoders respectively, and the sound signals are sent to two audio signal processors by a multiplexer which corresponds to the two microcontrollers to switch the sound signals of a single-receiving dual true diversity or a dual-receiving single true diversity. Thereafter, the sound signals are output by a sound signal mixer.

Systems, apparatuses, and methods are described for a privacy blocking device configured to prevent receipt, by a listening device, of video and/or audio data until a trigger occurs. A blocker may be configured to prevent receipt of video and/or audio data by one or more microphones and/or one or more cameras of a listening device. The blocker may use the one or more microphones, the one or more cameras, and/or one or more second microphones and/or one or more second cameras to monitor for a trigger. The blocker may process the data. Upon detecting the trigger, the blocker may transmit data to the listening device. For example, the blocker may transmit all or a part of a spoken phrase to the listening device.

A sound controlling system including a user terminal having a sound source, a wireless communication device, a digital to analog converter (DAC) and first processing electronics. The first processing electronics are configured to: provide data of a backing sound to the sound source; control the sound source to generate a sound signal based on the data; receive a first input instruction including a first instruction to transmit the sound signal and a second instruction to play back the backing sound; provide the sound signal to the wireless communication device as the first input instruction being the first instruction, and provide the sound signal to the DAC as being the second instruction; control the wireless communication device to convert the sound signal to a wireless signal and transmit the wireless signal; and convert the sound signal from a digital signal to an analog signal for play back of the backing sound.

When a speaker device is within communication range of an electronic device, various rules are used to determine whether to connect to or route audio data to the speaker device. For example, the electronic device may prompt the user to choose whether to connect to a wireless speaker device. In situations in which the user rejects connecting to the wireless speaker device, subsequent attempts by the speaker device to connect to the electronic device are also rejected or ignored without further prompting the user, or the wireless speaker device may be connected to the electronic device but audio data not routed to the wireless speaker device. By way of another example, the electronic device may determine whether to route audio data to a wireless speaker device based on signal strength and link quality metrics for wireless communication between the electronic device and one or more wireless speaker devices.

Various implementations include portable speakers with dynamic display characteristics. In some particular aspects, a portable speaker includes an enclosure housing: at least one electro-acoustic transducer for providing an audio output; a processor coupled with the at least one transducer; an audio input module coupled with the processor for receiving audio input signals; and a battery configured to power the at least one transducer, the processor, and the audio input module; an input channel for receiving a hard-wired audio input connection; at least one wireless input channel for receiving an audio input from a source device via a wireless connection; and a display on the enclosure coupled with the processor, wherein the processor adjusts an orientation of the display between a first orientation and a second orientation in response to detecting a change in orientation of the portable speaker.

Various implementations include portable speakers with detachable wireless transmitters. In some particular aspects, a portable speaker includes an enclosure housing: at least one electro-acoustic transducer for providing an audio output, a processor coupled with the at least one transducer; an audio input module coupled with the processor for receiving audio input signals; and an input channel for receiving a hard-wired audio input connection at the enclosure; at least one wireless transmitter detachably housed in the enclosure and in communication with a corresponding wireless input channel for receiving audio input from a source device.