The present disclosure relates to a method and an apparatus for automatically controlling a gain in an electronic device based on a sensitivity of microphone. The method according to an embodiment of the present disclosure includes outputting a reference audio to a speaker and obtaining a sound signal output by the speaker through a microphone, comparing a parameter of the obtained sound signal with a stored parameter, and adjusting a gain of the microphone based on a result of the comparing.

A device-adaptable headset device is provided, comprising: a microphone; one or more speakers; an audio connector comprising: a microphone output pin; and one or more speaker input pins respectively connected to the one or more speakers; a microphone line between the microphone output pin and the microphone; a ground line; one or more input devices in communication with the microphone line; a first circuit and a second circuit respectively configured for active signalling and passive signalling on the microphone line; and, a processor configured to: determine a present signalling mode; when the signalling mode is active, and when the one or more input devices is actuated, generate active signals on the microphone line using the first circuit; and, when the signalling mode is passive, and when the one or more input devices is actuated, generate passive signals on the microphone line using the second circuit.

Provided is an audio reproduction device including: a light source provided in the vicinity of a speaker unit; a detection unit that detects a beat of an audio signal reproduced by the speaker, and outputs a detection signal corresponding to the beat; and a light emission control signal output unit that controls a light emission mode of the light source in accordance with the detection signal, and outputs a light emission control signal for allowing generation of white light for a short period at a peak of intensity of the light source.

Audio spatial effects are provided using a gimbal-mounted ultrasonic speaker array in which a vertical line of ultrasonic speakers are provided on a speaker mount and are angled to direct sound at respective different elevation angles. The speaker mount can be rotated by a gimbal. In this way, the azimuth angle of the linear array is established in response to a control signal from, e.g., a game console or video player, with elevational angle of the desired sound beam being established by selecting one or more of the speakers in the linear array with the appropriate elevation angle.

An acoustic adjusting system includes an audio device and an earphone device. The audio device includes an acoustic adjusting module, an audio player, and a first communicating unit. The acoustic adjusting module generates an acoustic setting data; the audio player generates an audio signal; and the first communicating unit receives the acoustic setting data and the audio signal, and then outputs the acoustic setting data and the audio signal. The earphone device includes a second communicating unit, an erasable acoustic data memory, a digital signal processor, and an electroacoustic transducer. The acoustic setting data is stored in the erasable acoustic data memory by erasable means. The digital signal processor processes digitally the audio signal into a processed audio signal according to the acoustic setting data stored in the erasable acoustic data memory. The electroacoustic transducer converts the processed audio signal then plays it.

An earpiece includes an earpiece housing, a processor disposed within the earpiece, a speaker operatively connected to the processor, a microphone operatively connected the processor, and a global navigation satellite system (GNSS) receiver disposed within the earpiece. A system may includes a first earpiece having a connector with earpiece charging contacts, a charging case for the first earpiece, the charging case having contacts for connecting with the earpiece charging contacts, and a glob& navigation satellite system (GNSS) receiver disposed within the charging case.

A connector for a microphone and a microphone are provided that can prevent loose connections to a microphone stand. The connector for the microphone is to be inserted into a connector support hole of a microphone stand. The connector includes pins to be electrically connected to the microphone stand, a connector body accommodating the pins, a sleeve disposed on the outer circumferential surface of the connector body, and an elastic member for biasing the sleeve toward the rear end of the connector body. The sleeve has an insertion portion to be inserted into a space between the connector body and the connector support hole.

An awning assembly and method of construction is disclosed herein. The awning assembly comprising a first main arm for coupling to a dwelling, a second main arm rotatably coupled to the first main arm at a first end and supportingly coupled to a roll bar at a second end, the roll bar coupled to a canopy, and a hard wire connection housed within the first main arm for coupling to a power source. The awning assembly further comprising a detachable attachment module coupled to the first end of the second main arm and functionally coupled to the hard wire connection, the detachable attachment module comprising a plurality of electrical components, the plurality of electrical components comprising at least one of a microphone, a heating element, an input/output port, an image capture device, a speaker, an illumination source, and a transceiver.

A speaker integrated into a scanner is provided. The scanner comprises speaker firmware that presents the scanner as two separate logical devices to an Operating System (OS) of a connected host device. The integrated speaker of the scanner can be configured from the OS of the host device to be a primary or secondary speaker of the host device. The host device ports audio generated data on the host device over a wired or wireless connection to the speaker firmware, and the speaker firmware plays the host-generated audio data over or through the integrated speaker of the scanner.

One or more sensors are configured to contextualize a series of user generated movements to control one or more electronic devices. For example, a set of earphones comprises one or more sensors for sensing a location of the earphones. The one or more sensors enable earphones such as a pair of bluetooth or earphones wirelessly coupled to a bluetooth enabled electronic device, the capability to understand the configuration of use of the earphones. Based on a location and use or non-use of the earphones, one or more contextual responses is able to be applied for a given action.