An audio device includes a microphone, a sound canal allowing sound to pass from the surroundings to the microphone, a signal path from the microphone to a receiver, and a current source, such that sounds received at the microphone may be enhanced and presented at the ear level of the user. A protection screen is provided at the sound canal, and includes a first surface which faces the surroundings and a second surface which faces the sound canal, and defines a slit-formed opening between the first surface and the second surface. The curvature between the first surface and the slit-formed opening is smooth and gradual, and a sharp edge is located at the transition between the second surface and the slit-formed opening.

A microphone arrangement having an enlarged opening is disclosed. In an embodiment, the microphone includes a substrate, a transducer element arranged on the substrate, a cover having an opening, wherein the opening of the cover completely covers the transducer element and a sound separation fixing the cover to the transducer element.

Various aspects of the present disclosure are directed toward apparatuses, systems and methods that include an acoustic apparatus. The apparatuses, systems and methods may include an acoustic membrane and a protective housing defining an interior space in which the acoustic membrane is received.

A hybrid sensor assembly is configured to be mounted on a vehicle to sense structure borne and airborne noises generated as the vehicle travels over the roads. The sensor assembly includes a housing having a circuit board mounted therein, an accelerometer mounted on the circuit board, a microphone mounted on the circuit board, an acoustic port through the housing and in communication with the microphone, and an acoustic fabric attached to the housing over the port. An acoustic shield covers the acoustic port and substantially deters the entry of fluid and debris into the acoustic port.

The waterproof sound-permeable membrane of the present disclosure is a waterproof sound-permeable membrane adapted to permit passage of sound and prevent ingress of water. The air permeability of the waterproof sound-permeable membrane, as expressed by Gurley number, is 20 seconds/100 mL or more. The water entry pressure of the waterproof sound-permeable membrane is 500 kPa or more. When a tensile strength at break of the waterproof sound-permeable membrane in a MD direction is denoted by T1 and a tensile strength at break of the waterproof sound-permeable membrane in a TD direction orthogonal to the MD direction is denoted by T2, a strength ratio (T1/T2) is in a range of 0.5 to 2.0.

A semiconductor integrated device, comprising: a package defining an internal space and having an acoustic-access opening in acoustic communication with an environment external to the package; a MEMS acoustic transducer, housed in the internal space and provided with an acoustic chamber facing the acoustic-access opening; and a filtering module, which is designed to inhibit passage of contaminating particles having dimensions larger than a filtering dimension and is set between the MEMS acoustic transducer and the acoustic-access opening. The filtering module defines at least one direct acoustic path between the acoustic-access opening and the acoustic chamber.

A boot is used to cover an inlet of a microphone of an auditory prosthesis. The boot prevents water, sweat, and other debris from damaging the microphone or entering the prosthesis housing. Additionally, the boot can include structure that helps dampen vibrations within the auditory prosthesis, thus improving microphone performance.

An electronic device including a housing comprising one or more walls that define an interior cavity and that include a first wall having an audio opening extending through the first wall from an exterior surface of the housing to the interior cavity; a bracket disposed within the interior cavity and having first and second opposing surfaces, a first channel extending along the first surface and having a first end spaced apart from and surrounding the audio opening, and a second channel fluidly coupled to and extending perpendicular to the first channel through the second surface at a location laterally displaced from the audio opening; and a microphone disposed within the interior cavity and coupled to the second surface of the bracket over the second channel, wherein the bracket cooperates with the first wall to create an acoustic pathway that extends from the audio opening through the first wall, through the first channel and through the second channel to the microphone.

An air-permeable cover includes a substrate having a plurality of holes. The substrate has a first surface on which one end of each of the plurality of holes is open, and the first surface has a plurality of first protruding portions. The plurality of first protruding portions is arranged in regions between the plurality of holes on the first surface in accordance with an arrangement of the plurality of holes.

Embodiments describe a magnetic securing component including a set of magnets positioned laterally adjacent to one another and having a curved top surface defined by individual curved top surfaces of each magnet in the set of magnets. The set of magnets includes: first and second magnets positioned laterally adjacent to one another, where the first and second magnets each have a polarity that is oriented parallel to a vertical dimension; and third and fourth magnets laterally positioned from the first and second magnets, where the third magnet is positioned adjacent to the first magnet and the fourth magnet is positioned adjacent to the second magnet, the third and fourth magnets each having a magnetic polarity that is oriented at an angle with respect to the vertical dimension.