Disclosed herein are systems and methods for audio synchronization for hearing devices. An audio packet is received from a host device at a first hearing device configured to be worn in a first ear of a wearer, the audio packet compatible with a wireless low energy digital communication protocol, and the audio packet is received from the host device at a second hearing device configured to be worn in a second ear of the wearer. Upon one or more programmable conditions, a synchronization packet is sent from the first hearing device to the second hearing device. An acknowledgment packet is sent from the second hearing device to the first hearing device upon receipt of the synchronization packet, and a first transducer at the first hearing device and a second transducer at the second hearing device are unmuted to deliver synchronized audio to the first ear and to the second ear.

A method for adapting signal processing parameters of a hearing instrument of a hearing system. A number of acoustic indicators (IndA) for a temporary environmental situation of a user of the hearing instrument is ascertained from an input signal generated by a transducer. A first sensor ascertains a number of peripheral indicators (IndP) for the existing temporary environmental situation. Based on the acoustic and peripheral indicators (IndA, IndP) the system determines whether the existing temporary environmental situation falls into a known class of temporary environmental situations. If it does not, a new class is defined with the respective ascertained acoustic and peripheral indicator(s) (IndA, IndP), and the plurality of signal processing parameters are assigned a corresponding plurality of parameter values, according to which the first input signal is to be processed to form the output signal upon the future existence of a temporary environmental situation from the new class.

A hearing aid system for assisting a user's ability to hear includes at least one hearing aid instrument worn on the user's head. A sound signal from the surroundings is recorded and converted into input audio signals by input transducers of the hearing aid system. The hearing aid system includes two adaptive beamformers with variable notch direction, applied indirectly or directly to the input audio signals to generate direction-dependently damped audio signals. The notch directions are set to mutually different values to minimize the energy content of the direction-dependently damped audio signal of each beamformer. The notch directions of the two beamformers are evaluated in comparative fashion. A user's head rotation is captured qualitatively and/or quantitatively if a correlated change in the notch directions is determined within the scope of the comparative evaluation. A method for operating the hearing aid system is also provided.

A heart rate sensor within a hearing assistance device may provide heart rate information or other sensor data, which may be used to determine how well the hearing assistance device fits the patient's ear. The heart rate sensor data provides quantitative feedback that indicates how well the hearing assistance device fits the patient's ear. The heart rate sensor data may be used to provide an indication to the patient to reseat or otherwise adjust the fitting of the hearing assistance device. The improved fitting process provides the ability for the audiologist and patient to identify a preferred or optimized hearing assistance device geometry. This improved fit provides improved performance and reliability of the hearing assistance device.

A method of operating an in-situ fitting system (100) adapted to suggest an improved hearing aid parameter setting for a current user based on evaluated hearing aid parameter settings from a plurality of other users. The invention is also directed at an in-situ fitting system adapted to carry out said method.

Disclosed herein, among other things, are systems and methods for a user adjustment interface using remote computing resources. Specifically, a system can include a mobile device in communication with a hearing assistance device or a remote server. The mobile device can interpret an acoustic environment and send information about the environment to a remote server. The remote server can determine and send information to the mobile device for use in a user interface. The mobile device can receive a user selection of hearing assistance parameter information to be sent to the hearing assistance device.

A hearing aid system comprising at least a first hearing aid, wherein the first hearing aid is configured to establish a communication link over the internet with a remote entity based on a protocol stack, wherein the protocol stack includes an internet protocol, and the protocol stack is implemented in the first hearing aid.

Embodiments herein relate to audio systems including an ear-worn device and providing for remote audio stream management. In an embodiment, an audio system is included having an ear-worn device. The audio system can be configured to receive a notification regarding availability of a remote audio stream, query a wearer of the ear-worn device regarding the remote audio stream, receive an input from the wearer of the ear-worn device regarding the remote audio stream, selectively receive the remote audio stream, and selectively play the remote audio stream through the electroacoustic transducer. Other embodiments are also included herein.

A system may obtain a set of features characterizing a segment of inertial measurement unit (IMU) data generated by an IMU of an ear-wearable device. The system may apply a machine learning model (MLM) that takes the features characterizing the segment of the IMU data as input. The system may determine, based on output values produced by the MLM, whether a user of the ear-wearable device has potentially been subject to physical abuse. The system may then perform an action in response to determining that the user of the ear-wearable device has potentially been subject to physical abuse.

A wearable apparatus for hearing assistance, such as hearing glasses, is described. The wearable apparatus includes two microphones which are separated by a separation distance from each other. A display is included which is configured to present images in front of a user’s eyes. The wearable apparatus also has a processor to receive a first sound at a first time from a first microphone, receive the first sound at a second time from a second microphone, determine a direction of origin of the first sound based on the first time, the second time and the separation distance, and provide a visual indication of the direction of origin of the first sound using the display. The processor may also generate captions based on received speech and display the captions using the display.