Embodiments of this application provide an audio data processing method and apparatus, and a sound box system, which are related to the field of audio technologies, and improve sound quality of an audio playing device. The sound box system includes a full-frequency sound box and a low-frequency sound box. The full-frequency sound box is physically connected to the low-frequency sound box by using a first fastening part of the full-frequency sound box and a second fastening part of the low-frequency sound box. Furthermore, the full-frequency sound box communicates with the low-frequency sound box by using a first communication part of the first fastening part and a second communication part of the second fastening part, where the first fastening part and the second fastening part are a group of paired connection parts, and the first communication part and the second communication part are a group of paired communication parts.

Systems and methods are provided for an eyewear accommodating headset with adaptive and variable ear support. An example headset may comprise an ear cup with two or more distinct sections that differ in one or more characteristics. A first section is adaptively configured to accommodate a temple piece of a pair of eyeglasses of a wearer of the headset, and a second section is configured to maintain contact with a temple of the wearer of the headset. The different sections may comprise different foams (or different parts of foam, each with different characteristics). The characteristics may comprise hardness and/or density. Another example headset may comprise an ear cup with a divot that accommodates the temple piece of the eyeglasses.

A universal serial bus (USB) cradle includes a USB connector configured to engage the USB cradle with an external device. The USB further includes a cradle base integrated with the USB connector. The cradle base includes a cavity configured to accept an audio device in a docked configuration, and a magnetic connector configured to hold the audio device in a given position and orientation when the audio device is docked with the USB cradle.

An integrated acoustic coupler for use in sound engineering testing of an IEM (in-ear monitor). The integrated acoustic coupler comprises an integrated coupler body having an input, a first chamber and an output port. The input defines an IEM seat defined by a foam member and into an which an IEM may be inserted to define an air-tight seal between the foam and the IEM. The first chamber is in fluid communication with the IEM seat and interconnected with at least one second chamber via a passageway configured for creating compliance and impedance to simulate a human ear. The output port is configured for electronically interconnecting to an XLR cable and outputting a signal from an IEM under test to a mixer or audio analyzer.

An electronic apparatus that includes a first port configured to receive an incoming audio signal, a second port, and a controller configured to be coupled to the first port and the second port. The electronic apparatus further includes a switch configured to selectively decouple the controller from the second port when the first port receives the incoming audio signal. Decoupling the controller prevents an electrostatic discharge occurring on the second port from reaching the controller when the controller is receiving the incoming audio signal from the first port.

A directional microphone system includes a microphone assembly designed to be mounted from a ceiling or other raised surface through a reeling mechanism used to deploy the microphone assembly to a lowered position, preferably just above eye level of a speaker. The microphone assembly includes an outer housing encapsulating multiple audio detection elements or capsules which are specifically angled relative to each other and the horizontal in order to optimize targeted audio reception. With a preferred arrangement, three audio detection (microphone) elements are secured through with a wishbone frame mounted in the outer housing, with each element being at about a 60° angle to the horizontal to provide enhanced horizontal coverage.

An audio processor for digital audio data is provided, which comprises at least a host interface for connection to a digital audio host to transfer the digital audio data between the digital audio host and the audio processor; a device interface for connection to a user audio device; and a processing unit, connected with the host interface and the device interface. To allow a user to employ an audio device, such as a speaker or a pair of headphones of their choice when connecting to different digital audio hosts, said processing unit is configured to at least conduct a configuration procedure, in which the processing unit communicates with said digital audio host in one of at least a first communication mode and a second communication mode, wherein the communication modes differ from each other, and wherein the communication mode is selected according to the setting of a communication mode selector.

The present disclosure provides a wearable component. The wearable component includes a first carrier and a first electronic component at least partially embedded within the first carrier. The first carrier and the first electronic component define a space configured for audio transmission. An ear tip and a method of manufacturing a wearable component are also provided.

Methods and apparatus for gathering research data indicating exposure to media are disclosed. An example apparatus includes a first wireless receiver to receive a first modulated audio signal via a wireless data connection from a media device using a wireless communication protocol, the first modulated audio signal associated with the media, the first wireless receiver to output a baseband audio signal corresponding to the first modulated audio signal. The example apparatus includes a first wireless transmitter to modulate the baseband audio signal to form a second modulated audio signal, the first wireless transmitter to transmit the second modulated audio signal to wireless headphones using the wireless communication protocol. The example apparatus includes a monitoring device to receive the baseband audio signal, and to generate research data identifying the media, the media device including a second wireless transmitter to transmit the first modulated audio signal to the first wireless receiver, and the wireless headphones including a second wireless receiver to receive the second modulated audio signal from the first wireless transmitter.

A headset may comprise at least one ear cup and an ear cup shaper configurable into at least two configurations. When the ear cup shaper is configured in a first of the configurations, the ear cup is shaped to contact the temple of a wearer of the headset. When the adjustable ear cup shaper is configured in a second of the configurations, the ear cup is shaped to accommodate the temple piece of a pair of eyeglasses of a wearer of the headset. The ear cup may comprise a filler material such as foam, and the adjustable ear cup shaper when configured in the second of the configurations may create a depression in the foam. The adjustable ear cup shaper may comprise a strap and/or a plunger.