A hearing aid system (100), wherein changes to the settings is only allowed if a hearing aid performance verification is carried out with a successful result as well as a method of operating such a hearing aid system.

There is provided a method for streaming a multichannel audio signal comprising a first channel (L) and a second channel (R) from an audio source device to a binaural hearing system comprising a first hearing device worn at first ear of a user and a second hearing device worn at a second ear of the user.

Examples are disclosed that relate to changing an antenna pattern via one or more configurable parasitic antennas. One example provides a wireless device comprising a radio, a driven antenna connected to the radio, a ground plane, and one or more parasitic antennas. Each parasitic antenna connects to the ground plane via a switch operable to change an antenna pattern of the driven antenna.

A system and method for differentially locating and modifying audio sources that includes receiving multiple audio inputs from a set of distinct locations; determining a multi-dimensional audio map from the audio inputs; acquiring a set of positional audio control inputs applied to the audio map, each audio control input comprising a location and audio processing property; and generating an audio output according to the audio control inputs and the audio inputs. The audio control inputs capable of configuration through manual, automatic, computer vision analysis, and other configuration modes.

A method for transmitting information for adapting a hearing aid, in which an inquiry with regard to information of a partial process of the adaptation and/or a partial process of an operation of the hearing aid is transmitted by a first participant to a networked computer infrastructure. The inquiry is checked for conformity by the networked computer infrastructure with a plurality of stored partial process instructions. In the event that conformity with the inquiry is ascertained the corresponding partial process instruction is output to the first participant. In the event that no conformity of one of the stored partial process instructions with the inquiry is ascertained, the inquiry is output to a second participant, a partial process instruction corresponding to the inquiry is created with the co-operation of the second participant, and the partial process instruction corresponding to the inquiry is output to the first participant.

A system may obtain data related to hearing instruments, such as data indicating answers of a user to a questionnaire or historical usage data of the hearing instruments. For each respective feature of one or more features, the system may determine a feature duty cycle corresponding to an amount of time during a period in which the respective feature is anticipated to be active based on the data related to the hearing instruments. The system may further determine an energy cost for the respective feature at least based on the respective feature duty cycle for the respective feature and a power consumption rate of the respective feature. The system may calculate a battery life of one or more batteries in the hearing instruments at least based on the energy costs for each feature of the one or more features.

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.

A speaker of a hearing instrument generates a sound that includes a range of frequencies. Furthermore, a microphone of the hearing instrument measures an acoustic response to the sound. A processing system classifies, based on the acoustic response to the sound, a depth of insertion of an in-ear assembly of the hearing instrument into an ear canal of a user. Additionally, the processing system generates an indication based on the depth of insertion of the in-ear assembly of the hearing instrument into the ear canal of the user.

A hearing device configured to be worn at an ear of a user may include a sensor unit configured to provide sensor data, the sensor unit comprising a biometric sensor configured to provide biometric data included in the sensor data; and a processor configured to determine a physiological parameter from the sensor data, the physiological parameter indicative of a physiological property of the user. The processor is configured to determine whether the physiological parameter fulfills a condition, and provide, depending on whether the physiological parameter fulfills the condition, output data based on the sensor data, the output data including at least part of the biometric data and/or information derived from at least part of the biometric data different from the physiological parameter.

A system comprising a plurality of processing devices is arranged for performing an algorithm having a plurality of computational tasks. The plurality of processing devices are interconnected with each other. A control logic module is adapted to select an implementation of the algorithm among a plurality of implementations. At least a part of the control logic module resides in one of the processing devices and the implementation is selected according to at least one criterion of (latency requirements, computational power, resource availability, data locality, privacy requirements, precision requirements, hardware capabilities, distance, location, acoustical performance requirements, energy efficiency, orientation) and in the selected implementation the plurality of computational tasks of the algorithm is distributed over at least two of the processing devices.