A hearing device comprising a behind-the-ear module and a tube element extending from the behind-the-ear module is disclosed. The behind-the-ear module comprises a signal processor for processing received audio signals into a signal modified to compensate for a user's hearing impairment, and an antenna configured for emission and reception of electromagnetic radiation at a first frequency. The hearing device further comprises at least one electrically conducting element, wherein a first section of the at least one electrically conducting element extends into the tube element, and at least one decoupling element, the at least one decoupling element being configured to electrically decouple the first section and the behind-the-ear module at the first frequency while maintaining an electrical connection between the first section and the behind-the-ear module at second frequencies.

Disclosed is a hearing device configured to be worn in an ear of a user. The hearing device is configured to provide an audio signal to the user. The hearing device comprises a circuit assembly. The circuit assembly comprises a printed circuit board assembly. The printed circuit board assembly comprises: a first circuit board; a second circuit board; and a third circuit board interconnected with the first circuit board and the second circuit board. The circuit assembly comprises a battery, and an output transducer for providing the audio signal, wherein the printed circuit board assembly is folded about the battery and the output transducer.

A hearing assisting (10) device including a receiver (1) for generation of acoustic signals and a fixture (3, 8, 9) for positioning the receiver. A suspension (2, 21, 22) supports the receiver to the fixture. The combination of the receiver and the suspension has a mechanical resonance frequency in the range from 6 kHz to 10 kHz.

A hearing device to be worn in or at the ear of a user. The hearing device includes a housing for accommodating an electronic component, wherein the housing includes an electromagnetic wave shielding material and is formed with an indentation. The indentation provides a space at the outer side of the housing, allowing an antenna to be inserted into the indentation. The proposed hearing device achieves improved shielding of the antenna against electromagnetic waves radiated from at least one of the electronic components.

Embodiments of the present invent include a method of controlling unwanted vibration in a tympanic lens, wherein the tympanic lens comprises a perimeter platform connected to a microactuator through at least one biasing element, the method comprising the step of: damping the motion of the at least one biasing element. In embodiments of the invention, the at least one biasing element is a spring. In embodiments of the invention, the at least one bias spring is coated in a damping material.

Low-cost hearing aid platforms that are customizable for specific user needs are disclosed. An exemplary hearing aid platform includes an electret microphone, an amplifier, a capacitor, a printable circuit board (PCB), an audio output, and a housing for the components. The hearing aid platform may comprise customizable gain settings and safety features such as automatic gain control. In some embodiments, the hearing aid platform may connect to headphones. In some embodiments, the hearing aid platform may connect to a bone transducer. Devices described herein also may include housings that are customizable for a user's needs and/or personality.

A hidden cochlear implant system comprises a canal unit and an implanted unit. The canal unit comprises at least one canal microphone; a canal modulator; a canal transmitting antenna: and a canal electrical power source, wherein the at least one canal microphone is electrically connected to the canal modulator, the canal modulator is electrically connected to the canal transmitting antenna, and the canal electrical power source is electrically connected to any component of the canal unit that requires supply of electrical power. The implanted unit comprises a cochlear receiving antenna; a processor; and an electrode array, wherein the cochlear receiving antenna is electrically connected to the processor, and the processor is electrically connected to the electrode array. Additional embodiments of the hidden cochlear implant are disclosed herein.

An ear tip for a hearing device includes a body member having a receiver retention portion that is communicably coupled to a sound port. The receiver retention portion is configured to receive and capture a receiver such as a balanced armature receiver. An electrical interface of the receiver is accessible via an opening in the receiver retention portion. The ear tip also includes an ear interface portion that is disposed at least partially about the body member. The ear interface portion is configured to be disposed in a user's ear canal. The ear interface portion and the body member are integrally formed as a unitary member.

A hearing device is provided. The hearing device comprises a first portion configured to be arranged at a head of a user and to provide a signal to a second portion.

Methods and devices for measuring vibration of an implanted driven vibrating elongate body coupled to a bone of the middle ear, for example using an accelerometer coupled to the vibrating body. The measured vibration can be taken during implantation and long again after implantation to check for possible decoupling, disease, or additionally impeded vibratory driving of the middle ear bone. An accelerometer signal can be converted to a displacement value and used to check for an under impeded or over impeded vibratory body. An implanted device can be used to periodically check the vibration of the vibratory body. Methods and devices can be used in conjunction with implanted devices which receive vibratory signals from a middle ear bone and use the signals to drive a disarticulated middle ear bone closer to the ear drum.