The present disclosure relates to a hearing instrument comprising a rechargeable battery source providing a battery supply voltage and a switched capacitor DC-DC converter comprising a DC input coupled to the battery supply voltage for converting the battery supply voltage into a higher or lower DC output voltage. The hearing instrument comprises at least one active circuit connected to the DC output voltage for energizing active components of the at least one active circuit.

An exemplary auditory prosthesis system for a patient includes a body-worn sound processor apparatus configured to control an operation of a cochlear implant, a headpiece configured to facilitate wireless coupling of the body-worn sound processor apparatus to the cochlear implant, an audio accessory that includes a microphone configured to receive incoming audio and convert the incoming audio into an audio signal, a first communication port configured to connect directly to a communication port of the body-worn sound processor apparatus by way of a first cable, a second communication port configured to connect directly to a communication port of the headpiece by way of a second cable, and a control module communicatively coupled to the microphone and the first and second communication ports and that is configured to provide the audio signal to the body-worn sound processor apparatus by way of the first cable.

A hearing protection system, a hearing protection device and related method, the hearing protection device comprising an earpiece device comprising a first connector, a first earpiece, and a second earpiece, the first earpiece comprising a first primary microphone and a first receiver wired to the first connector and the second earpiece comprising a second primary microphone and a second receiver wired to the first connector; and a processing device comprising a processor, an earpiece interface, and a wireless communication interface, wherein the processor is configured to receive a first microphone input signal from the first primary microphone; process the first microphone input signal for provision of a first primary output signal for the first receiver based on the first microphone input signal; receive a communication request from a communication device via the communication interface; and in response to receipt of the communication request, communicate with the communication device via the communication interface.

An exemplary auditory prosthesis system includes an audio accessory configured to be external to a patient and that includes 1) a plurality of microphones that receive incoming audio and convert the incoming audio into a plurality of audio signals, 2) a first communication port that connects directly to a communication port of a body-worn sound processor apparatus by way of a first cable, 3) a second communication port that connects directly to a communication port of a headpiece by way of a second cable, and 4) a control module communicatively coupled to the plurality of microphones and the first and second communication ports and that generates a processed audio signal by processing the plurality of audio signals converted by the plurality of microphones from the incoming audio and provides the processed audio signal to the body-worn sound processor apparatus.

The present disclosure relates to a hearing instrument comprising a rechargeable battery source providing a battery supply voltage and a switched capacitor DC-DC converter comprising a DC input coupled to the battery supply voltage for converting the battery supply voltage into a higher or lower DC output voltage. The hearing instrument comprises at least one active circuit connected to the DC output voltage for energizing active components of the at least one active circuit.

The present disclosure relates to a hearing instrument comprising a rechargeable battery source providing a battery supply voltage and a switched capacitor DC-DC converter comprising a DC input coupled to the battery supply voltage for converting the battery supply voltage into a higher or lower DC output voltage. The hearing instrument comprises at least one active circuit connected to the DC output voltage for energizing active components of the at least one active circuit.

A media system and a method of using the media system to accommodate hearing loss of a user, are described. The method includes selecting a personal level-and-frequency dependent audio filter that corresponds to a hearing loss profile of the user. The personal level-and-frequency dependent audio filter can be one of several level-and-frequency-dependent audio filters having respective average gain levels and respective gain contours. An accommodative audio output signal can be generated by applying the personal level-and-frequency dependent audio filter to an audio input signal to enhance the audio input signal based on an input level and an input frequency of the audio input signal. The audio output signal can be played by an audio output device to deliver speech or music that the user perceives clearly, despite the hearing loss of the user. Other aspects are also described and claimed.

The presently disclosed subject matter includes a mobile compute device configure to produce a set of audiological assessment data based on a set of stimulus signals presented to a user via a source device and a set of response signals provided as a response to the set of stimulus signals. The mobile compute device identifies a personal audiological profile of the user at least based on a psychoacoustic model and the set of audiological assessment data. The mobile compute device builds a digital signal processing model including a set of audio digital signal processing functions. The mobile compute device executes the digital signal processing model to produce an output audio signal in response to an input audio signal received from the source device, the output audio signal is based on a modified version the input audio signal. The mobile compute device transmits the output audio signal via the source device.

An assistive listening device includes a microphone arrangement for capturing an input microphone audio signal; a microphone signal processing unit for processing the input microphone audio signal so as to generate a processed microphone audio signal; a USB interface for connecting to a communication device, the USB interface comprising a USB audio input port to receive a USB input audio signal from the communication device and a USB audio output port to transmit a USB output audio signal to the communication device; a USB audio signal processing unit for processing the USB input audio signal so as to generate a processed USB input audio signal; a wireless interface for transmitting an output audio signal via a wireless link to a hearing device; and a control unit for selecting one of a first, second and third streaming mode and for operating the assistive listening device according to the selected streaming mode.

The hearing system comprises a finger ring and a hearing device body. The finger ring includes: a first short-distance wireless communication portion; a vibration output portion disposed at a position that contacts a finger to convert a voice signal, which is received by the first short-distance wireless communication portion, into a cartilage conduction vibration and outputs it; and a first power source portion that supplies power to the first short-distance wireless communication portion and the vibration output portion. The talk device body includes: a second short-distance wireless communication portion that communicates with the first short-distance wireless communication portion; a microphone; a voice signal output portion that makes the second short-distance wireless communication portion output the voice signal according to a voice captured by the microphone; and a second power source portion that supplies power to the second short-distance wireless communication portion, the microphone, and the voice signal output portion.