Presented herein are acoustic port covers for attachment to electronic devices. An electronic device includes a housing having at least one acoustic port extending through the housing. An acoustic port cover in accordance with embodiments presented herein is configured to be detachably coupled to the housing so as to cover the at least one acoustic port and function as a barrier to the accumulation of foreign materials/contaminants at a protective membrane associated with the at least one acousticport.

Embodiments are directed to an electronic device configured to measure temperature from within an ear canal having a first bend, a second bend, and a tympanic membrane. The device comprises an enclosure comprising an in-canal section dimensioned for deployment in the ear canal. The in-canal section comprises a trough extending axially along at least a portion of the in-canal section and arranged to be positioned between the first bend and the tympanic membrane when the in-canal section is fully deployed in the ear canal. A temperature sensor is disposed in the trough. The temperature sensor comprises a flexible circuit board, a distal temperature sensor disposed on the flexible circuit board, and a proximal temperature sensor disposed on the flexible circuit board and situated proximal of, and spaced apart from, the distal temperature sensor in an outer ear direction.

In one embodiment, the present invention is directed to a contact hearing system including: an ear tip including a transmit circuit having a first Q value, wherein the ear tip includes a transmit coil wound on a ferrite core; a contact hearing device including a receive circuit having a second Q value, wherein the first Q value is greater than the second Q value; a receive coil positioned on the contact hearing device, wherein the receive coil includes a core of a non-ferromagnetic material.

The present disclosure relates to a hearing aid and detachable speaker unit assembly. The detachable speaker unit assembly comprises a fastening structure to provide an enhanced removal force and stable insertion into the ear canal of the user.

An auditory device includes an electronics module, a receiver and a cable connecting the electronics module to the receiver. The electronics module includes an enclosure shaped to be positioned behind an outer portion of either a left ear or a right ear of a user and circuitry within the enclosure. The receiver is configured for being located in either a left or a right ear canal of the user. When inserted into the left ear canal, the receiver occupies a left ear canal insertion position, and when inserted into the right ear canal, the receiver occupies a right ear canal insertion position. The cable and the receiver are shaped and configured such that the receiver is presented in a neutral position when no external force other than gravity is acting upon the receiver, the neutral position being between the left ear canal insertion position and the right ear canal insertion position.

A hearing aid (600) includes an earpiece (602), a casing (604), and coupling member (612). The earpiece (602) is configured to sit at least partially within the user’s ear canal when worn. The casing (604) supports a sound processor (608) and a microphone (606) and is configured to sit behind a users ear and in contact with the user’s pinna when worn. The coupling member (612) couples the casing (604) to the earpiece (602). The coupling member (612) has an effective length that is adjustable to accommodate users with different ear geometries.

A hearing device has a housing in which a receiver is arranged as an electrical component. An antenna arrangement is formed, which has a winding in the form of a coil, which is arranged around the receiver with the interposition of a shielding foil. The shielding foil has a section extending around the receiver and several lugs adjoining it, which project beyond the receiver, the lugs enclosing between them an interspace adjoining the receiver. The shielding foil has in particular two layers, namely a magnetic layer and an electrical shielding layer. By this arrangement an antenna arrangement with high sensitivity is formed and at the same time a shielded partial area is created in the inter-space in which further components can be arranged. Due to the design of the lugs, which are particularly flexible, they can be attached to an inner wall of a housing.

The present disclosure relates to a hearing device assembly comprising a behind-the-ear base unit and an in-the-ear transducer module, which communicate via a single wire interface and wherein the base unit is configured to take on a communication role in response to a signal asserted by the transducer module.

A hearing aid including a hearing aid antenna assembly, a transceiver, and an acoustic transducer is provided. The hearing aid assembly includes a resonant loop antenna, a coupling mechanism such as a primary loop, and an electrically conductive assembly. The resonant loop antenna forms an aperture that is arranged to be substantially parallel to a head of the wearer when the hearing aid is worn. The coupling mechanism is configured to transfer RF energy between the transceiver and the resonant loop antenna. The resonant loop antenna excites the electrically conductive assembly. The electrically conductive assembly includes a battery shield. The resonant loop antenna, the coupling mechanism, and/or the electrically conductive assembly are formed in one or more conductive layers of FPCB. The resonant loop antenna includes a course tuning capacitor in series with a fine tuning capacitor. The primary loop includes a resonating capacitor.

A system includes an image sensor, a hearing device, and a controller. The controller may include one or more processors and may be operatively coupled to the image sensor and the audio sensor. The controller may be configured to receive image data from the image sensor and sound data from the hearing device. The controller may further be configured to identify one or more optical components using the image data, each of the one or more optical components associated with an object or activity; determine one or more audio objects using at least the one or more optical components and the sound data, the one or more audio objects may each include an association between at least a portion of the sound data and the object or activity; and adjust an audio class using the one or more audio objects, the audio class associated with the object or activity.