An earpiece is provided. The earpiece can deform flexibly so as to follow the earhole when in use, and the earpiece can be manufactured easily. An earpiece includes an earpiece body and a filler filled in the earpiece body. The earpiece body has a container-like base member formed of a rubber-like elastic diaphragm that is shaped like a container and has an opening portion. The earpiece body also has a lid member that seals the opening portion liquid-tightly. The filler is flowable at room temperature.

A hearing aid contains a housing having a baseplate and a housing shell, a number of electrical units, and a transmitting and receiving unit for transmitting and receiving electromagnetic waves. The number of electrical units are fastened on the baseplate. The transmitting and receiving unit includes an electronic circuit for generating a transmission signal and an antenna unit coupled thereon, and the antenna unit includes a first antenna arm and a shielding element for shielding the first antenna arm against the number of electrical units.

The use of the correct, required length of a cable in a hearing aid substantially contributes to the wearing comfort of the hearing aid. At least one ear depiction of an ear is created by a camera. An associated ear geometry is determined on the basis of the ear depiction. The required length of the cable for the hearing aid can in turn be determined by use of the ear geometry.

A hearing aid, in particular constructed as a classical hearing aid, includes a housing having a baseplate and a housing shell, a number of electrical and/or electronic units, and a transmitting and receiving unit for transmitting and receiving electromagnetic waves. The number of electrical and/or electronic units are fastened on the baseplate. The transmitting and receiving unit includes an electronic circuit for generating a transmission signal and an antenna unit coupled thereon. The antenna unit includes a free arm and the transmitting and receiving unit is configured to inductively feed the transmission signal of the electronic circuit into the antenna unit.

A system may have a rechargeable hearing instrument with a power source, an ultraviolet (UV) sensor configured to convert received UV light into electrical power and charging circuitry coupled to the UV sensor and to the power source. The charging circuitry may use the electrical power to charge the power source. A charger may have a charging cavity configured to receive the rechargeable hearing instrument. A power source within the charger powers a UV light source located within the charger configured to provide UV light to the UV sensor of the rechargeable hearing instrument when the rechargeable hearing instrument is placed within the charging cavity.

A computing device is described that obtains a representation of a target ear canal of a user. Using a machine-learned model that has been trained based at least in part on representations of previously fabricated ear-wearable devices, the computing device generates a representation of an ear-wearable device for the target ear canal.

A hearing device and related methods are disclosed. The hearing device comprises a housing comprising a wall, a microphone inlet comprising a through-going opening, a microphone arranged within the housing for receiving audio via the microphone inlet, a first filter device comprising a first filter material, the first filter device being arranged at the microphone, and a second filter device substantially having the shape of a torus or a hollow cylinder and comprising a second filter material, the second filter device being arranged at the wall, wherein the first filter device is arranged between the microphone and the second filter device, and wherein the through-going opening comprises an outer recess in an outer surface of the wall, wherein the second filter device is arranged in the outer recess.

An ear-wearable electronic device includes aa shell having a uniquely-shaped outer surface that corresponds uniquely to an ear geometry of a user of the ear-wearable device. The device includes a mounting structure that is formed contiguously with the shell and intersects an inner surface of the shell. The mounting structure includes a mounting surface operable to fixably mount an interchangeable device to the shell. The mounting structure defines a void that extends from the inner surface to the outer surface of the shell. The mounting structure has a reference feature that is positioned relative to the outer surface of the shell such that the interchangeable device is located at a target orientation relative to the outer surface.

An ear-wearable electronic device is housed within a shell. The shell includes an organically-shaped outer surface that corresponds uniquely to an ear geometry of a user of the ear-wearable device. The shell also has a faceplate void that has a curved and beveled perimeter edge. The faceplate void facilitates access to one or more devices installable into the shell. A faceplate is installed in the faceplate void. The faceplate has a beveled edge that mates with the perimeter edge. The faceplate includes an unbroken covering surface that matches the outer surface of the shell surrounding the faceplate void.

An earphone and a method for manufacturing an earphone are disclosed. The earphone comprises, a housing, including an outer housing and/or an inner housing, and a speaker unit, including a static structural part, wherein at least one portion of the static structural part is integrated with at least one part of the outer housing and/or inner housing.