An assembly of a sound generator having a sound output, a spout connected to the receiver, the spout having a sound channel having a first opening connected to the sound output and a second opening from which sound may be output. The spout has one or more third openings blocked by fastening portions of a dome, and a sensor positioned in the sound channel at the third opening(s). Sound may pass the sensor in the sound channel while travelling in the third opening(s). The assembly may be a personal hearing instrument and the sensor may be a microphone.

The disclosure relates to a device for preparing an earpiece for its customization, the device including an energy release unit comprising a receiving chamber for receiving the earpiece and configured to release energy into the receiving chamber. The disclosure further relates to a system for customizing an earpiece comprising the earpiece and the preparing device.

A method for monitoring placement of a first physiologic sensor of a hearing device with respect to an ear of a user, the first physiologic sensor configured to monitor a heart rate of the user of the hearing device, includes: obtaining first physiologic sensor data from the first physiologic sensor at the hearing device; obtaining second physiologic sensor data from a second physiologic sensor at an external device, the second physiologic sensor configured to detect the heart rate of the user; performing a comparison based on the first physiologic sensor data from the first physiologic sensor, and the second physiologic sensor data from the second physiologic sensor; and setting a reference physiologic sensor data based on the first physiologic sensor data and/or the second physiologic sensor data if the comparison results in a match, or providing a notification if the comparison does not result in a match.

The present disclosure relates to a hearing device assembly comprising a behind-the-ear base unit and an in-the-ear transducer module, which communicate via a single wire interface and wherein the base unit is configured to take on a communication role in response to a signal asserted by the transducer module.

Embodiments of the invention are directed to a microactuator including using (i) an ingress membrane mounting ring adhesive positioned on an ingress membrane mounting surface to mount an ingress membrane and (ii) a flexible encapsulation shield mounted on a support band and extending over the ingress membrane mounting ring and (iii) a first reed adhesive connecting the ingress membrane to a microactuator reed at an ingress membrane reed opening and (iv) a second reed adhesive positioned on and covering the first reed adhesive, the second reed adhesive extending from the ingress membrane to the microactuator reed.

A method is disclosed for operating a hearing device, comprising a receiver and an active vent. The method includes 1) upon request to switch the active vent into a different state, estimating a transfer function (H, H.sub.rec.fwdarw.mic) from the receiver to obtain a first transfer function (Ĥ.sub.a), 2) subsequently switching the active vent, 3) subsequently estimating a transfer function (H, H.sub.rec.fwdarw.mic) from the receiver to obtain a second transfer function (Ĥ.sub.b), 4) comparing the first transfer function (Ĥ.sub.a) to the second transfer function (Ĥ.sub.b) to obtain a divergence measure (D), 5) concluding that the active vent has actually been switched into the different state if the divergence measure (D) exceeds a threshold (D.sub.diff).

The present disclosure relates to a socket connector for a hearing device. The hearing device comprises a Behind-The-Ear (BTE) unit and a Receiver-In-the-Ear (RIE) unit, the BTE unit comprising a frame, wherein the frame comprises electronic components of the BTE unit, the RIE unit comprising a plug connector configured for providing an electrical connection between the RIE unit and the BTE unit. The socket connector is connectable to the frame of the BTE unit and is configured for detachably connecting the plug connector to the frame.

A hearing assistance device, including a housing, a receiver, and a cable, is provided. The housing has an ear hook and a first contour arc. The cable faces the ear hook, penetrates the housing, and connects to a receiver.

Techniques used to selectively amplify audio signals are described in connection with audio amplification devices, such as hearing aids. A device and its operation are described to facilitate setting low and high tone/volume controls separately, using at least two selection mechanisms. In one aspect, a first selection mechanism includes a pitch frequency control rocker switch and the second selection mechanism includes a bass frequency control rocker switch disposed separately. In one aspect, the bass frequency control rocker switch causes a processor to bias the frequency response of the sound amplifier for frequencies below 1 kHz. In another aspect, the pitch frequency control rocker switch causes a processor to bias the frequency response of the hearing for frequencies above 1 kHz. In another aspect, the selection mechanism involves the separate attenuation of treble and bass adjustments in response to a user selection of a rocker switch setting for each adjustment.

As described in some examples of this disclosure, a Behind-The-Ear (BTE) hearing instrument comprises processing circuity, a battery that stores energy for use by the processing circuitry, and a housing that contains a receiver configured to output sound. The receiver is positioned within the hearing instrument posterior to the processing circuitry and the power source.