A hearing assistance system having an audio signal wireless transmission unit for transmitting a stereo audio signal with left and right ear channels, a first ear unit for being worn at a user's ear and having a hearing instrument and a wireless audio signal receiver unit, the hearing instrument providing the first receiver unit with information as to which ear of the user the hearing instrument is being worn and information as to whether, or not, there is a like second ear unit. The first receiver unit is adapted to decide, depending on the received information as to which ear the first hearing instrument is fitted and whether a second ear unit is worn at the other ear, to receive one of the right and left ear channels, and, in absence of a stereo channel, to supply the respective mono channel of the audio signal to the first hearing instrument.

A hearing assistance system streams audio signals from one or more streaming sources to a hearing aid set and enhances the audio signals such that the output sounds transmitted to the hearing aid wearer include a spatialization effect allowing for localization of each of the one more streaming sources. The system determines the position of the hearing aid set relative to each streaming source in real time and introduces the spatialization effect for that streaming source dynamically based on the determined position, such that the hearing aid wearer can experience a natural feeing of the acoustic environment.

An audio playing system has a first channel output device, a first equalizer and a controller. The first equalizer is electrically coupled to the first channel output device and having a set of first parameters of frequency response, the first equalizer configured to adjust a first channel audio signal with the set of first parameters of frequency response and output the adjusted first channel audio signal to the first channel output device. The controller is electrically coupled to the first channel output device and the first equalizer, wherein in a test mode, the controller is configured to send a set of test audio signals to the first channel output device, to generate a set of first user parameters based on a plurality of pieces of first confirmation signal, and to adjust the set of first parameters of frequency response based on the set of first user parameters.

The application relates to a binaural hearing assistance system comprising first and second hearing assistance devices adapted for being located at or in left and right ears of a user. The application further relates to a method of operating a binaural hearing assistance system. The object of the present application is to provide an improved binaural hearing assistance system. The problem is solved in that each of the first and second hearing assistance devices comprises a) a first wireless interface comprising first antenna and transceiver circuitry adapted for establishing a first communication link to the respective other hearing assistance device based on near-field communication; b) a second wireless interface comprising second antenna and transceiver circuitry adapted for establishing a second communication link to an auxiliary device based on far-field communication; c) a link control unit operatively coupled to the second antenna and transceiver circuitry and configured to repeatedly provide a second link quality measure indicative of a link quality of the second communication link; wherein the first and second hearing assistance devices are configured to exchange said respective second link quality measures between them via said first and/or second communication links. This has the advantage of providing a robust and flexible system. The invention may e.g. be used for binaural hearing assistance systems, e.g. binaural hearing aid systems, where audio quality and power consumption has to be mutually optimized.

The application relates to a binaural hearing assistance system comprising first and second hearing assistance devices adapted for being located at or in left and right ears of a user. The application further relates to a method of operating a binaural hearing assistance system. The object of the present application is to provide an improved binaural hearing assistance system. The problem is solved in that each of the first and second hearing assistance devices comprises a) a first wireless interface comprising first antenna and transceiver circuitry adapted for establishing a first communication link to the respective other hearing assistance device based on near-field communication; b) a second wireless interface comprising second antenna and transceiver circuitry adapted for establishing a second communication link to an auxiliary device based on far-field communication; c) a link control unit operatively coupled to the second antenna and transceiver circuitry and configured to repeatedly provide a second link quality measure indicative of a link quality of the second communication link; wherein the first and second hearing assistance devices are configured to exchange said respective second link quality measures between them via said first and/or second communication links. This has the advantage of providing a robust and flexible system. The invention may e.g. be used for binaural hearing assistance systems, e.g. binaural hearing aid systems, where audio quality and power consumption has to be mutually optimized.

A system (202) for binaural signal processing. A first speaker (210) and a second speaker (220) are respectively mounted proximal to, and deliver respective first and second acoustic signals to, the left and right ears of a user. A first microphone (212) and a second microphone (222) are respectively mounted proximal to the left and right ears. A binaural processing device receives signals from the microphones and, based on the microphone signals, determines the first and second acoustic signals. The binaural processing device operates at a distance from both the left and right ears of the user. The speakers, microphones and the binaural processing device are connected by a signal network.

A method and a device are provided for modifying audio signals in accordance with hearing capabilities of an individual who is listening to audio signals played by a music player. The method comprises the steps of: providing a music player operative to play audio signals, wherein the music player comprises a processor configured to modify audio signals that are about to be played, by taking into account the hearing capabilities of the individual; providing information that relates to the hearing capabilities of the individual; forwarding the information that relates to the hearing capabilities of the individual, from an electronic device to the music player; and using the music player processor to modify audio signals when the individual is listening to audio signals being played by the music player, wherein the audio signals are modified before they are played by taking into account the individual's hearing capabilities.

Aspects of the subject disclosure may include, for example, identifying first and second users and identifying first and second locations of the first and second users in a presentation area, determining first and second media content associated with the first and second users where the first media content includes first audio content and first video content and where the second media content includes second audio content, presenting the first video content at a display device during a particular time period, adjusting the first audio content resulting in adjusted first audio content, presenting the adjusted first audio content directed to the first location during the particular time period, and presenting the second audio content directed to the second location during the particular time period. Other embodiments are disclosed.

A system for capturing an individual's hearing characteristics, including loudness tolerance levels at different sound frequencies, as an individualized shaped auditory profile for automatically enhancing audio to complement and address an individual's hearing deficits experienced via a particular signal pathway including the audio device, the sound environment, and the individual's hearing capabilities. The auditory profile is used to produce enhanced sound subsequently transmitted to the individual via the same signal pathway. The enhanced sound may be produced with consideration of both ears' auditory profile shapes together to increase the dynamic range of the enhanced sound. The sound enhancement can be introduced gradually over a sound reproduction session or a period of time of use. Manual gain adjustments applied by multiple users to particular sound enhancement are recorded and used in pattern recognition to allow the system to learn and suggest alternatives to the desired sound enhancement for the auditory profile.

A setup application in a TV, sound bar, surround sound speaker system, or AVR creates a hearing profile for a user, calibrating various frequencies according to an interactive calibration step. Then, object-based audio, which may include metadata describing the key aspects of the audio, is used to identify the key aspects so that they can be emphasized, using the calibration information, to allow for increased intelligibility and the most natural listening experience possible for the hearing-impaired. EQ calibration for each speaker also may be effected for each user.