A hearing aid device for use in bone anchored hearing aid solutions is disclosed. The hearing aid includes at least one user input unit for controlling an operation mode of the hearing aid device, at least one signal line connecting the at least one user input unit with a control unit for controlling the hearing aid device, and an antenna module comprising at least two electrically conductive and electrically connectable layers forming a layered structure. The at least one user input unit is arranged at one of the layers of the antenna module, and the at least one signal line is provided at an inner surface of one of the layers facing one other layer.

A hearing device includes a housing with a retention flange defining a retention space. A conduit is disposed about an electrical wire electrically coupled to a transducer and a ferrule is disposed about an end portion of the conduit and fixed along an axial dimension of the conduit, the ferrule having a portion disposable in the retention space. A bushing has a portion disposed at least partially about the portion of the ferrule disposable in the retention space, the bushing formed of a soft material relative to a hardness of the ferrule and the housing, wherein the bushing is located between the retention flange and the ferrule and the retention flange captures the conduit relative to the housing when the portion of the bushing is disposed in the retention space.

Disclosed herein, among other things, are apparatus and methods for a hearing assistance device with a sensor hub. Various aspects of the present subject matter include a method of using a hearing assistance device. A method includes sensing biometric signals from a wearer of a hearing assistance device using one or more sensor modules included in or on a receiver housing of the hearing assistance device, the receiver housing configured to connect to an end of a cable and configured to be placed in or near an ear canal of the wearer. The method also includes transmitting data indicative of the sensed biometric signals from the one or more sensor modules to a sensor hub in a connector of the cable, and processing the data using the sensor hub.

A method for operating an external component of a cochlear implant hearing system. The external component includes a speech processor module operable in a stand-alone mode of operation and a body-worn mode of operation, and a protective case. The method includes operating the speech processor module in the stand-alone mode, determining when the speech processor module is mounted in the case, and operating the speech processor module in the body-worn mode in response to determining that the speech processor module is mounted in the case.

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.

An exemplary hearing system that is configured to assist a user in hearing includes an in-the-ear (“ITE”) component that comprises a shell having a contoured outer shape that is customized for the user to fit at least partially within an ear canal of the user, a faceplate configured to fit within an opening provided in the shell and face out of the ear canal of the user when the shell is inserted into the ear canal of the user, a sensor electrode that is provided on an outer surface of the shell, and a conductive path that extends along the outer surface of the shell from the sensor electrode to the faceplate and that conductively connects the sensor electrode with a conductive portion of the faceplate. Corresponding methods and systems are also disclosed.

A hearing instrument is specified having a rechargeable battery, a charging coil for inductively receiving energy for charging the battery, a transmitter and/or receiver coil electrically separated from the charging coil for inductively transmitting and/or receiving data, and a magnetic core. Both the charging coil and the transmitter and/or receiver coil are wound on the magnetic core.

A flexible arm that is configured to be located between and physically and electrically connect an acoustic module of an open-ear headphone to a battery housing of the open-ear headphone. The flexible arm defines an original resting length and position between the acoustic module and the battery housing. The flexible arm includes a flexible printed circuit that extends through the entire original resting length of the flexible arm and comprises a conductor that is configured to carry electrical energy between the acoustic module and the battery housing, and a flexible material that encases at least some of the flexible printed circuit. The length of the flexible printed circuit within the flexible arm is greater than the original resting length of the flexible arm. The flexible printed circuit can thus better accommodate tension or compression on the flexible arm as the flexible arm is bent from its original resting position.

A simple hearing enhancement device that takes the normally adequately loud sound levels and optimizes selective frequency gain of the patient's ear passage to improve speech comprehension.

A hearing instrument includes: a first portion shaped and sized for placement at a pinna of a user's ear; and a second portion having an earpiece for placement in the user's ear canal; wherein the second portion also comprises a connector assembly configured for electrically coupling to the first portion, the connector assembly having a plurality of connector wires, the plurality of connector wires comprising a first connector wire; wherein the second portion also comprises a receiver or miniature loudspeaker for receipt of an audio drive signal through at least the first connector wire; and wherein the second portion also comprises a non-volatile memory circuit having a data interface configured for receipt and transmittal of module data, the non-volatile memory circuit configured to store the module data, wherein the stored module data at least comprises electroacoustic calibration parameter(s) of the receiver or the miniature loudspeaker.