A binaural hearing aid system comprises left and right hearing instruments each comprising a BTE-part comprising a housing configured to be located at or behind an outer ear of the user and an acceleration sensor configured to measure acceleration in at least two directions relative to the housing of the BTE-part and to provide acceleration data indicative thereof. A first one of the left and right hearing instruments comprises a transmitter configured to transmit said acceleration data to the other hearing instrument, and the other hearing instrument comprises a receiver for receiving said acceleration data from the first one of the hearing instruments. The other hearing instrument further comprises a controller for detecting whether or not the left and right hearing instruments are correctly mounted in dependence of a similarity measure between said acceleration data provided by the left and right hearing instruments. A method of operating a binaural hearing aid system is further disclosed.

An accessory eyeglasses retention device is integrally formed as a single elastomeric piece to secure eyeglasses to a wearer's head. The accessory eyeglasses retention device may include an elongated body extending between a front end and a back end, an adjustment mechanism including a first elastic strap and a second elastic strap, for example, longitudinally spaced apart on the elongated body and configured to hold a temple of the eyeglasses and adjustably position the elongated body relative to the temple. An angled flap is at the back end of the elongated body, extending and angled in a direction towards a portion of the wearer's head when the eyeglasses are worn on the wearer's head, and configured to securely retain the eyeglasses in a desired location on the wearer's head. Also, a lanyard attachment feature may be included at the back end of the elongated body and configured to attach the elongated body to an eyeglasses lanyard.

A hearing device includes a loudspeaker having a loudspeaker diaphragm for generating acoustic signals, a drive or actuator acting on the loudspeaker diaphragm, and a loudspeaker housing in which the drive or actuator and the loudspeaker diaphragm are accommodated. A housing encloses a housing interior. A loudspeaker box is disposed in the housing interior and has a sound outlet opening coupled with a sound conductor leading out of the housing. The loudspeaker is sealed in the loudspeaker box against the housing interior in a fluid-tight manner. The loudspeaker is disposed in the loudspeaker box clear or free of a sound channel element, disposed within the loudspeaker box and coupling the loudspeaker with the sound outlet opening.

A method is indicated for operating a hearing aid, wherein the hearing aid is switchable between a usage state, in which a signal processing unit of the hearing aid is activated, and an idle state, in which the signal processing unit is deactivated. The hearing aid has a time measuring unit, which has a first timer and a second timer. The first timer is activated in the usage state and is deactivated in the idle state, for time measurement during the usage state. The second timer is activated in the idle state for time measurement during the idle state. Furthermore, a corresponding hearing aid is indicated.

The invention relates to a hearing device. The hearing device comprises an outer shell, the outer shell defining an outer compartment. The hearing device further comprises a receiver, and a rechargeable battery electrically connected to the receiver. Finally, the hearing device comprises a sealed inner compartment arranged in the outer compartment, wherein the receiver and the rechargeable battery are both arranged in the sealed inner compartment.

An ear-worn electronic hearing device comprises an enclosure configured to be supported by, at, in or on an ear of the wearer. Electronic circuitry is disposed in the enclosure and comprises a wireless transceiver. An antenna is disposed in or on the enclosure and operably coupled to the wireless transceiver. The antenna has a physical size and comprises a plurality of cutouts disposed along a periphery of the antenna. The cutouts are configured to increase an electrical length of the antenna without an increase in the physical size of the antenna. The antenna can comprise at least one interior window having a window periphery. A plurality of window cutouts are disposed along the window periphery. The window cutouts are configured to increase a path length of current distribution along the window periphery.

An exemplary hearing system that is configured to assist a user in hearing includes an in-the-ear (ITE) component configured to fit at least partially within an ear canal of the user while the hearing system is worn by the user, a first sensor electrode provided on a surface of the ITE component and configured to contact, while the hearing system is worn by the user, outer ear tissue of the user, and a second sensor electrode configured to be located, while the hearing system is worn by the user, at an entrance to or outside of the ear canal of the user. The first sensor electrode and the second sensor electrode may be configured to be used to detect a physiological attribute of the user while the hearing system is worn by the user. Corresponding methods and systems are also disclosed.

An external component of a prosthesis, including a first module including a functional component and first structure including magnetic material. The first module is configured to be retained against skin via a magnetic field at least partially generated by a magnet implanted in a recipient that interacts with the magnetic material of the first structure, the first module including a skin interfacing surface configured to interact with skin of the recipient when the first module is retained against the skin of the recipient, a second module including a second structure including magnetic material configured to enhance magnetic retention of the external component to skin of a recipient, wherein the second module is removably attached to the first module and visible from an outside of the external component when the second module is attached to the first module and when viewed from a side opposite the skin interfacing side.

A method for adjusting a hearing device (12) adapted to be worn behind an ear (28) comprises: determining a cymba angle (54) between a cartilage (50) above the cymba (46) of the ear (28) and a viewing direction (38) of the user; estimating a tilt angle (39) of the hearing device (12) with respect to the viewing direction (38) from the cymba angle (54); and adjusting a beam former direction (37) of a beam former (34) of the hearing device (12), such that the beam former direction (37) is aligned with the viewing direction (38).

A hearing aid assembly includes a receiver speaker enclosed within a receiver housing. The receiver housing defines a circuitous receiver acoustic channel, wherein the receiver channel defines an open side along at least a portion of the receiver channel. The receiver channel also defines a pass-through passage extending from a first side of the receiver housing to a second side of the receiver housing, wherein the pass-through passage is partially defined by the wall defining a receiver opening. The hearing aid assembly also includes an earbud configured to fit over at least a portion of the receiver housing and partially cover the open side of the receiver channel.