A processing device is interfaced with an auditory region of the brain of a subject that is responsible for auditory perception. The processing device receives signals associated with nerve impulses that are transmitted to the auditory region of the brain of the subject in response to sound collected by an ear of the subject. The processing device processes the received signals and generates at least one audio signal that is representative of the auditory perception, by the subject, of the sound collected by the ear. In certain embodiments, the processing device processes at least one audio signal that is representative of at least one sound to convert the at least one audio signal to a sequence of nerve impulses, and selectively provides the sequence of nerve impulses to the auditory region of the brain of the subject such that the subject audially perceives the at least one sound.

An expert diagnosis system integrated in a hearing prosthesis system is configured to diagnosis, grade, and remediate inner ear crises. In particular, the expert diagnosis system analyzes combinations of in-situ measured inner ear potentials, obtained in response to electrical and/or acoustic stimulation, in order to identify crisis signatures and to correlate those crisis signatures to clinical symptoms of a specific type and cause of an inner ear crises (i.e., automatically diagnosis the inner ear crisis). The expert system is further configured to grade the severity of the identified clinical symptoms and initiate some form of remedial action to address the identified inner ear crisis.

Presented herein are in-situ techniques for monitoring a recipient's cochlea health to proactively identify (i.e., predict) changes to the recipient's cochlea health outside of a clinical setting. The cochlea health monitoring techniques presented herein obtain one or more cochlea health biomarkers associated with a recipient's cochlea health, such the recipient's residual hearing, and analyze these biomarkers to predict that a cochlea health change is likely to occur.

Presented herein are techniques for dynamically setting, in real-time, a ratio of acoustical stimulation signals to electrical stimulation signals delivered by a hearing prosthesis. The ratio of the acoustical stimulation signals to the electrical stimulation signals is set based on one or more characteristics or attributes of the input sound signals that are received and processed by the hearing prosthesis in order to generate the acoustical and electrical stimulation signals.

An improved implantable auditory stimulation system includes two or more implanted microphones for transcutaneous detection of acoustic signals. Each of the implanted microphones provides an output signal. The microphone output signals may be combinatively utilized by an implanted processor to generate a signal for driving an implanted auditory stimulation device. The implanted microphones may be located at offset subcutaneous locations and/or may be provided with different design sensitivities, wherein combinative processing of the microphone output signals may yield an improved drive signal. In one embodiment, the microphone signal may be processed for beamforming and/or directionality purposes.

A hearing aid comprises an input transducer configured to convert sound around a user to at least one electrical input signal representing the sound; an output transducer for providing an audible signal based on the at least one electrical input signal; transceiver circuitry configured to establish a wireless audio communication link with a secondary device; and a processor configured to operate the hearing aid in a system mode or a device mode. The hearing aid is configured to initiate establishment of the wireless audio communication link in dependence of a mode control signal. A non-wearable device comprising transceiver circuitry configured for establishing a wireless audio communication link with a hearing aid comprises a processor configured to receive and process at least one electrical input signal from a hearing aid to at least partially compensate for hearing impairment of a user; a power supply interface. The non-wearable device is integrated with another device having a specific other function.

An implantable processor arrangement is described for an active implantable medical device (AIMD) system implanted under the skin of a patient. An implantable communications coil arrangement is configured for transdermal transfer of an implant communications signal. An implantable processor is coupled to and controls the implantable communications coil arrangement so as to operate in two different communications modes. In a normal operation mode, the processor configures the communications coil arrangement for peridermal communication with an external communications coil placed on the skin of the patient immediately over the implantable communications coil arrangement. In a long range telemetry mode, the processor configures the communications coil arrangement for extradermal communication with an external telemetry coil located distant from the skin of the patient immediately over the implantable communications coil arrangement.

A hearing aid comprises a resulting beam former (Y) for providing a resulting beamformed signal Y.sub.BF based on first and second electric input signals IN.sub.1 and IN.sub.2, first and second sets of complex frequency dependent weighting parameters W.sub.11(k), W.sub.12(k) and W.sub.21(k), W.sub.22(k), and a resulting complex, frequency dependent adaptation parameter β(k)•β(k) may be determined as <C.sub.2*•C.sub.1>/<(|C2|.sup.2>+c), where * denotes the complex conjugation and • denotes the statistical expectation operator, and c is a constant, and wherein said adaptive beam former filtering unit (BFU) comprises a smoothing unit for implementing said statistical expectation operator by smoothing the complex expression C.sub.2*•C.sub.1 and the real expression |C.sub.2>.sup.2 over time. Alternatively, β(k) may be determined from the following expression

[00001]$\beta =\frac{w_{C.Math..Math.1}^H.Math.C_v.Math.w_{C.Math..Math.2}}{w_{C.Math..Math.2}^H.Math.C_v.Math.w_{C.Math..Math.2}},$

where w.sub.C1 and w.sub.C2 are the beamformer weights representing the first (C.sub.1) and the second (C.sub.2) beamformers, respectively, C.sub.v is a noise covariance matrix, and H denotes Hermitian transposition. Corresponding methods of operating a hearing aid, and a hearing aid utilizing smoothing β(k) based on adaptive covariance smoothing are disclosed.

A button sound processor, including an RF coil, such as an inductance coil, and a sound processing apparatus and a magnet, which can be a permanent magnet, wherein the button sound processor has a skin interface side configured to interface with skin of a recipient, and the button sound processor is configured such that the magnet is installable into the button sound processor from the skin interface side.

Presented herein are pre-operative surgical planning techniques that enable a user to optimize placement of an implantable component of an implantable medical device in/within the body of a recipient. In particular, a computing device/system is configured to obtain anatomical data associated with the part body of the recipient in which the implantable component is to be implanted. The computing system is configured to analyze the recipient anatomical data to determine one or more suggested implantable placements for the implantable component. The computing device may be configured to predict, at least based on the recipient anatomical data, an estimated outcome for the recipient with the implantable component implanted at a suggested implantable placement.