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.

In embodiments of the invention, the present invention is directed to a contact hearing system, the contact hearing system including: an ear tip, the ear tip including a transmit coil wherein the transmit coil is wound around a core including, at least in part, a ferromagnetic material; and a contact hearing device including a receive coil wherein the receive coil is wound around a core including, at least in part, a non-ferromagnetic material.

Systems and methods for assisting user with hearing by amplifying sound using an amplifier with gain and amplitude controls for a plurality of frequencies; and applying a learning machine to identify an aural environment and adjust the amplifiers for optimum hearing.

The invention relates to a tool for inserting an ear-tip of a hearing aid into an auditory canal of an end user. The tool comprises a first part and a second part, which are movable in relation to each other around at least one pivot joint. A cavity for receiving a holding portion of the ear-tip is provided between the first and the second part, which cavity is enlarged when a second portion of the first part and a second section of the second part are pressed together.

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 includes a shell with a cable retention slot. The cable entrance slot has an interior end and an exterior end. A bend surface extends from the exterior end of the cable retention slot to an exterior surface of the shell. The bend surface aligned with a crux of a user’s ear when the ear-wearable device is installed in an ear of the user’s ear. The shell may include a uniquely-shaped outer surface that corresponds uniquely to an ear geometry of the user of the ear-wearable device.

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.

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.

Disclosed examples include devices that are wearable at a recipient’s pinna and configured to deliver bone-conduction vibrations directly to the pinna. The device can be so configured by having a vibration transfer surface disposed within the pinna when the device is worn. The devices can lack a component configured to deliver vibrations to a non-pinnal surface, such as the ear canal. The devices can include a projection configured to be disposed within a recipient’s ear canal that is vibrationally decoupled from the remainder of the device.

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.