An electronic device with a display is paired with a set of wireless audio output devices, including a first wireless audio output device for outputting audio to a right ear of a user and a second wireless audio output device for outputting audio to a left ear of the user. In response to a request to display status information about the set of wireless audio output devices, the electronic device displays a status user interface, including concurrently displaying a first battery status indicator for the first wireless audio output device with an indication that battery status indicator relates to the device for outputting audio to the right ear of the user and a second battery status indicator for the second wireless audio output device with an indication that battery status indicator relates to the device for outputting audio to the left ear of the user.

There is provided a hearing aid with an antenna connected to a transmission and/or reception circuit for transmission and/or reception of the electromagnetic energy via the antenna. A coupling circuit, e.g. including a directional coupler, is configured to sense an electric return power from the antenna, and to generate a power signal based on the sensed electric return power. A controllable impedance circuit is connected to the antenna, so as to allow adjusting of impedance of the antenna in at least two different steps. A processor is configured to generate a tuning control signal to the controllable impedance circuit in response to the power signal. This allows control of the impedance of the antenna for minimizing impedance mismatch, and thus improve performance of the antenna by tuning the impedance to the operating conditions of the antenna, preferably in an automatic manner.

A device includes a network interface to communicate with a communication network and a microphone to convert sounds into an electrical signal. The device further includes a processor coupled to the microphone and the network interface. The processor is configured to process the electrical signal to generate acoustic data based on the electrical signal and to provide the acoustic data to the network interface for transmission to a data storage device.

Various systems and methods are disclosed herein to increase the quality of the sound delivered to a user and allow personalization to optimize listening performance and comfort under atypical listening conditions, environment specific adjustment, and data capture to assist in the personalization of the system to the user's needs and preferences. Features disclosed include sound level rating systems that aggregate noise data detected by user's mobile phones or hearing devices to provide a database of real-time noise levels. Additionally, a user's sound settings may be saved in the system by location so that they may be recalled when re-entering a specific location. A remote clinician may tune a hearing device, or a user can tune the device using a pre-recorded audio sample. Also, a user may replay the last X seconds of audio recorded by their hearing device.

The present disclosure relates to tracking of acoustic feedback events of a hearing assistance device, such as a hearing aid. Information about the acoustic feedback events is stored for analysis. Such information is useful for programming acoustic feedback cancellers and other parameters of a hearing assistance device.

A hearing device configured to be worn by a user comprises one or more microphones, a processing unit, a speaker, a wireless communication unit, and stress evaluator. The user wearing the hearing device is in an environment defined by an acoustic scene. The microphones receive audio signals from audio sources in the environment and provide them to the processing unit which applies processing parameters to thereby process the audio signals. The speaker provides the processed audio signals to the user. The stress evaluator generates an indication of stress of the user, stress of the user being related to the acoustic scene. The processing unit then decides whether to perform an action on the basis of the received audio signals and the indication of stress of the user.

A processing system determines, based on a set of input datapoints, a current state of charge (SOC) of a battery of a hearing instrument. Additionally, the processing system determines a predicted agenda of the hearing instrument, the predicted agenda comprising one or more future time segments. The processing system estimates, based on the current state of charge and the predicted agenda of the hearing instrument, an amount of time remaining until the future SOC of the battery of the hearing instrument reaches a threshold.

Presented herein are techniques for detecting sensory outcome issues through an analysis of data representing the direction of incidence/arrival of a sensory input and inertial data representing movement of the recipient's head following detection of the sensory input. By correlating recipient head movement (including lack of movement) with the arrival direction of the sensory input, a sensory prosthesis system can determine whether or not the recipient acted as expected and, if not, whether a sensory outcome problem is present.

An exemplary method for fitting a hearing device to a hearing device user performed by a fitting system operatively connected to but remote from the hearing device includes providing, to the hearing device, an adjustable parameter identified by a fitter using a fitting system and a specification comprising an allowed range for the adjustable parameter defined by the fitter using the fitting system. The method further includes transferring the adjustable parameter and the specification to a user interface operatively connected to the hearing device and located with the hearing device for use by the hearing device user, receiving an adjusted parameter value for the adjustable parameter adjusted by the hearing device user with aid of the user interface to be within the allowed range, and updating the adjustable parameter in a transfer function of the hearing device based on the adjusted parameter value.

A method operates a hearing device, in which an adaptation to the hearing device by a hearing device wearer is determined. An ambient situation is detected, and a value is assigned to the ambient situation. The value is used as a degree of adaptation. A hearing device includes a microphone for detecting the ambient situation and a hearing device system includes a hearing device, as well as the use of a hearing device and a computer program product.