A liquid-resistant acoustic assembly for an electronic device includes an acoustic device positioned in a housing, a gasket compressed between the acoustic device and the housing, and a liquid-resistant membrane. The liquid-resistant membrane is disposed such that it is isolated from a non-uniform compressive distribution resulting from compression of the gasket. The liquid-resistant membrane may be uncompressed by compression of the gasket or compressed by a different compressive force than the gasket. For example, the liquid-resistant membrane may not be positioned between the gasket and the acoustic device, may be separated from the gasket, may be mounted to a shelf of the gasket or within a gap defined by the gasket, mounted to a stiffener positioned within the gasket, and mounted using other similar configurations.

A recorder receives designation of a video which is desired to be reproduced from a user. If designation of one or more designated locations where sound is emphasized on a screen of a display which displays the video is received by the recorder from the user via an operation unit during reproduction or temporary stopping of the video, a signal processing unit performs an emphasis process on audio data, that is, the signal processing unit emphasizes audio data in directions directed toward positions corresponding to the designated locations from a microphone array by using audio data recorded in the recorder. A reproducing device reproduces the emphasis-processed audio data and video data in synchronization with each other.

The present invention is a microphone that incorporates a system of removable covers that can change the acoustic characteristics of the microphone, provide enhanced environmental protection for the microphone, and add additional features through electronic sensors and other means. The invention consists of one or more microphone capsules mounted inside of an enclosure, which has a physical fastening system such as flanges, screw threads, or other means. This fastening system mates with a variety of microphone covers that can change the characteristics of the microphone. These covers may act as wind screens, acoustic baffles, phase cancellation guides, water and dust seals, impact bumpers, and may also add additional functionality through the incorporation of electronic sensors

An acoustic waterproof structure is provided according to the present application, which includes a casing, a waterproof breathable film, a stretchable material piece and a rigid supporting piece. A casing sound hole is provided on the casing, one side of the waterproof breathable film is sealed and connected to the casing and covers the casing sound hole, and the other side of the waterproof breathable film abuts against the stretchable material piece. A stretchable material piece sound hole is provided on the stretchable material piece; at least one through hole is provided on the rigid supporting piece, one side of the rigid supporting piece is sealed and connected to the casing and extrudes the stretchable material piece, and the other side of the rigid supporting piece is configured to connect to an acoustic device.

A microphone includes a microphone base that has a first surface and a second surface. The microphone also includes a microelectromechanical system (MEMS) device coupled to the first surface of the microphone base. The microphone also includes a cover coupled to the first surface of the microphone base, such that the cover divides the first surface into a covered portion where the cover encloses the MEMS device, and a non-covered portion extending away from the cover. The microphone also includes one or more pads on the uncovered portion of the first surface of the base. The microphone also includes a port extending through the base from the first surface to the second surface.

Particular embodiments described herein provide for an electronic device that includes a plurality of audio acquisition areas. Each of the plurality of audio acquisition areas can include a microphone element to detect audio data, an audio opening that allows the audio data to travel to the microphone element, and a windscreen that covers at least the audio opening. An audio module can be configured to receive the audio data from each of the plurality of audio acquisition areas and enhance the audio data.

Described herein is a sensor probe for association with a portion of an aircraft. The sensor probe includes a microphone assembly having a portion configured to receive audio signals. The sensor probe further includes a nosecone associated with the microphone assembly. The nosecone assembly is configured to shield the portion of the microphone assembly from noise generated by direct impact of an airflow for a plurality of local flow angles.

A hands-free harmonica microphone for controlling undesired audio feedback, the microphone comprising: a reflective curved microphone chamber, a harmonica mount, a transducer, associated electronics and a neck brace attachment apparatus for connecting the microphone to commercially available harmonica holders (neck braces). In one embodiment, the harmonica mount is detachably coupled (magnetically or otherwise) to the microphone chamber. In another embodiment, the harmonica mount is integrated to the microphone chamber so that is also possible to mount the harmonica directly onto the microphone chamber.

A mobile device may include an enclosure and a rear cover assembly affixed to a back portion of the enclosure. The rear cover assembly may include a protruding portion that extends above a surrounding portion of the rear cover assembly. The protruding portion may include a number of through holes that extend through the protruding portion of the rear cover assembly. In one through hole, a tubular microphone may be provided. The tubular microphone may include a microphone enclosure which may contain a MEMS microphone device, an integrated circuit, and an interposer positioned between the MEMS microphone device and the integrated circuit. A height of the tubular microphone may be substantially similar to a thickness of the protruding portion and the tubular microphone may be entirely or partially disposed within a through hole of the protruding portion.

The sound-permeable membrane of the present invention is adapted, when placed over an opening for directing sound to or from a sound transducer, to prevent entry of foreign matters into the sound transducer through the opening while permitting passage of sound, the sound-permeable membrane including a non-porous film or a multilayer membrane including the non-porous film. The non-porous film is formed of oriented polytetrafluoroethylene. This sound-permeable membrane has an unconventional configuration and exhibits various excellent properties. At least one principal surface of the non-porous film may have a region subjected to a surface modification treatment.