Disclosed embodiments include systems and methods of configuring, e.g., a hearing prosthesis comprising a beamforming microphone array having two or more microphones. Some embodiments include (i) storing a plurality of sets of beamformer coefficients in memory, where each set of beamformer coefficients corresponds to one of a plurality of zones on a recipient's head, and (ii) configuring the hearing prosthesis with a set of beamformer coefficients that corresponds to the zone on the recipient's head where the beamforming microphone array is located. Other embodiments include determining a set of beamformer coefficients based on magnitude and phase differences between microphones of the beamforming array, where the magnitude and phase differences are determined from a plurality of head related transfer function measurements for the microphones.

An aural iris includes a lumen and an actuator coupled on or in or to the lumen for at least partially attenuating sound traversing through the lumen by selectively actuating the actuator on and off. Other embodiments are disclosed.

Methods and systems are described for transferring programming information to a hearing instrument. Such programming information may include hearing loss compensation parameters and/or other information pertaining to device operation. In one embodiment, each of a pair of hearing instruments prescribed and configured for a particular hearing loss contains the necessary information for operation on either the left or right ear. The data from one hearing instrument may then be transferred to the other hearing instrument by means of wireless communication. In other embodiments, programming information is transferred wirelessly by an external device connected to a database.

Presented herein are directed to techniques for using objective measurements to determine a combined efficiency of an implantable actuator and a mechanical coupling of the implantable actuator to an auditory structure of an ear of a recipient. In particular, the implantable actuator is activated so as to deliver, via the mechanical coupling, mechanical stimulation to the auditory structure to effect a pressure change in an inner ear of the recipient. At least one stimulation device, that is separate from the implantable actuator, is configured to deliver secondary stimulation to the recipient to also effect a pressure change in the inner ear of the recipient. Objective measurements are performed to intra-operatively capture auditory evoked responses of the recipient in response to the mechanical stimulation and in response to the secondary stimulation. These auditory evoked responses are analyzed to determine a vibratory coupling efficiency.

Systems and methods for processing an audio signal are provided for server-mediated sound personalization on a plurality of consumer devices. A user hearing test is conducted on one of a plurality of audio output devices. Next, the hearing data of the user's hearing test is outputted to a server and stored on the server's database along with a unique user identifier. Next, a set of DSP parameters for a sound personalization algorithm are calculated from the user's hearing data. The DSP parameter set is then outputted to one of a plurality of audio output devices when the user logs in with their unique identifier on an application on the audio output device.

Embodiments for using an intelligent hearing aid device by a processor. Audio data may be received and analyzed for a user according to a plurality of user preferences and interests, historical activity patterns of the user, or a combination thereof. One or more hearing assistive actions may be performed in relation to the audio data to facilitate hearing according to the plurality of user preferences and interests, historical activity patterns of the user, or a combination thereof.

A hearing improvement system for use with a user's smart device and earpiece/headphones includes software stored on a memory device of the smart device, the software configured to be executed by a processor of the smart device to cause an audio signal received from a microphone of or operating with the smart device if containing two or more sound patterns to be separated into a plurality of individualized sound patterns; categorize the individualized sound patterns; display an icon representing each categorized sound pattern on a screen of the smart device; enable a user viewing the icons to at least one of deactivate or activate each of the individualized sound patterns; and enable each of the non-deactivated individualized sound patterns to be delivered to the user's earpiece/headphones.

A method includes determining a first feature of a first audio signal at a first location in a signal processing path and determining, using the first feature, a first environmental classification of the first signal. Further, the method includes, based on the first environmental classification, enabling, modifying or disabling one or both of a first signal processing mode at the first location and a second signal processing mode at a second location in the signal processing path. The method also includes determining a second feature of a second audio signal at the second location and determining, using the second feature, a second environmental classification of the second signal. Further, the method includes, based on the second environmental classification, enabling, modifying or disabling one or both of the first signal processing mode at the first location and the second signal processing mode at the second location.

A system, method, hearing aid and software for providing a network connection for a computer device to at least one hearing aid having a gateway to the Internet. The system includes a user account server providing a user account database, each user account includes a unique identity for an associated hearing aid; a control server providing a hearing aid connection register including the unique identity of hearing aids associated with current connection information; and a network connection handling element for detecting the presence of a wireless connection between the hearing a and gateway, and for uploading current connection information to the control server. On receiving connection information, the control server updates the hearing aid connection register, and provides the current connection information to a requesting computer device. The computer device can establish a direct connection to the hearing aid based on current connection information requested from the control server.

A method for providing feedback of an own voice loudness of a user of a hearing device comprises: extracting an own voice signal of the user from an audio signal acquired with a microphone of the hearing device; determining a sound level of the own voice signal from the audio signal; determining an acoustic situation of the user; determining at least one of a minimal threshold and a maximal threshold for the sound level of the own voice signal from the acoustic situation of the user; and notifying the user, when the sound level is at least one of lower than the minimal threshold and higher than the maximal threshold.