The present disclosure relates to compact hearing aids, components thereof, and support systems therefor, as well as methods of insertion and removal thereof. The compact hearing aids generally include a sensor, such as a microphone, an actuation mass, an energy source for providing power to the compact hearing aid, a processor, and an actuator enclosed in a housing that is designed to be inserted through the tympanic membrane during a minimally-invasive outpatient procedure. In operation, the microphone receives sound waves and converts the sound waves into electrical signals. A processor then modifies the electrical signals and provides the electrical signals to the actuator. The actuator converts the electrical signals into mechanical motion, which actuates the actuation mass to modulate the velocity or the position of the tympanic membrane.

Various embodiments of a hearing device and a system of using such device are disclosed. The hearing device includes a housing, electronic components disposed within the housing, and an earpiece adapted to be disposed in an ear canal of the ear of the wearer. The device also includes a sensor adapted to be in contact with a portion of the ear of the wearer, where the sensor is further adapted to detect a physiological characteristic of the wearer and generate a sensor signal based on the physiological characteristic that is received by a controller of the electronic components disposed within the housing; and a cable that operatively connects the sensor to the earpiece, where the cable is biased to maintain contact between the sensor and the portion of the ear of the wearer when the earpiece is disposed in the ear canal of the wearer.

Various embodiments of a hearing device and a system of using such device are disclosed. The hearing device includes a housing, electronic components disposed within the housing, and an earpiece adapted to be disposed in an ear canal of the ear of the wearer. The device also includes a sensor adapted to be in contact with a portion of the ear of the wearer, where the sensor is further adapted to detect a physiological characteristic of the wearer and generate a sensor signal based on the physiological characteristic that is received by a controller of the electronic components disposed within the housing; and a cable that operatively connects the sensor to the earpiece, where the cable is biased to maintain contact between the sensor and the portion of the ear of the wearer when the earpiece is disposed in the ear canal of the wearer.

A completely-in-canal hearing aid, including a housing, a receiver, a chip, a battery, a flexible circuit board and a microphone, wherein the housing includes a front section and a rear section; the receiver and the chip are located in the front section; the battery is located in the rear section; the rear section has two opposite surfaces and two opposite side surfaces; the front section has a first central axis parallel to the length of the front section; the rear section has a second central axis located between the two opposite surfaces and between the two opposite side surfaces; the first central axis and the second central axis are different straight lines. The completely-in-canal hearing aid is fine and compact in structure, reasonable and ingenious in design, diversified in function and comfortable to wear.

Presented herein are low-power active bone conduction devices that comprise an actuator that is subcutaneously implanted within a recipient so as to deliver mechanical output forces to hard tissue of the recipient. The low-power active bone conduction devices include an energy recovery circuit configured to extract non-used energy from the actuator and to store the non-used energy for subsequent use by the actuator. The low-power active bone conduction devices may also include a multi-bit sigma-delta converter that operates in accordance with a scaled sigma-delta quantization threshold value to convert received signals representative of sound into actuator drive signals.

An ultrasonic audio transducer system includes an ultrasonic speaker. The ultrasonic speaker may be an electrostatic emitter, a piezoelectric emitter (single crystal or stack), a piezoelectric film emitter, or any other emitter capable of emitting ultrasound. The ultrasonic speaker is configured to be coupled (via a wired or wireless connection) to an audio modulated ultrasonic carrier signal from an amplifier, wherein upon application of the audio modulated ultrasonic carrier signal, the ultrasonic speaker is configured to launch a pressure-wave representation of the audio modulated ultrasonic carrier signal into the air. Additionally, the ultrasonic speaker may be implemented with an impedance matching element or optimized for matching the response within a user's ear canal, and the ultrasonic audio transducer system may include The ultrasonic audio headphone system can further include a frequency mismatched microphone to avoid feedback when the microphone and the ultrasonic speaker are, e.g., proximately located.

The disclosed technology relates to a hearing aid system (HS) comprising a first hearing aid device (2), which is designed for arrangement in an ear canal (1.1), and a second hearing aid device (3), which is designed for arrangement near to the first hearing aid device (2), wherein the first hearing aid device (2) and the second hearing aid device (3) each comprise at least one microphone, one signal processing unit, one loudspeaker and one battery, such that both the first hearing aid device (2) and the second hearing aid device (3) can each function as a hearing aid device independently of the respective other of the hearing aid devices (2, 3). Furthermore, the disclosed technology relates to a method for operating the hearing aid system (HS).

The disclosed technology relates to a hearing aid system (HS) comprising a first hearing aid device (2), which is designed for arrangement in an ear canal (1.1), and a second hearing aid device (3), which is designed for arrangement near to the first hearing aid device (2), wherein the first hearing aid device (2) and the second hearing aid device (3) each comprise at least one microphone, one signal processing unit, one loudspeaker and one battery, such that both the first hearing aid device (2) and the second hearing aid device (3) can each function as a hearing aid device independently of the respective other of the hearing aid devices (2, 3). Furthermore, the disclosed technology relates to a method for operating the hearing aid system (HS).

A hearing aid device including sensors are disclosed. Specifically, a hearing aid with a temperature sensor and a reference sensor. Also disclosed is a method for estimating body core temperature.

A hearing aid device including sensors are disclosed. Specifically, a hearing aid with a temperature sensor and a reference sensor. Also disclosed is a method for estimating body core temperature.