Abstract: A method for determining the level of stimulation signals generated by an auditory prosthesis as a result of processing an electrical audio signal representative of sound is disclosed, the method comprising: converting the audio signal into a plurality of frequency-based signal components; analyzing one or more of the signal components to determine a quantity associated with the presence of a target signal in the analyzed signal component; and calculating the signal level based on the determined quantity when the determined quantity indicates a target signal is sufficiently present in the audio signal.

Abstract: The present disclosure describes systems and methods to transition a hearing prosthesis between different stimulation strategies. In accordance with one embodiment, a method is provided and includes operating a hearing prosthesis in accordance with a first parameter, receiving an instruction to operate the hearing prosthesis in accordance with a second parameter, and in response to the receiving, transitioning to operate the hearing prosthesis in accordance with the second parameter by operating the hearing prosthesis in accordance with at least one intermediate parameter.

Abstract: A method for delivering drugs from an implantable medical device to an implantee, comprising implanting the medical device having a receptacle configured to receive a drug release capsule, the drug release capsule having at least one drug disposed thereon, placing the drug release capsule in the receptacle subsequent to the implanting, and permitting the release of the at least one drug from the drug release capsule to the recipient.

Abstract: The sound processor and method uses a model of basilar membrane motion to select stimuli, based upon the predicted motion which the acoustic signal presented would produce in an acoustically excited normally hearing cochlea. The filter; used, in contrast to single channel per electrode approaches, cover multiple channels and overlap with each other. Consequently the stimuli presented produce a neural excitation pattern which approximates the spatio-temporal travelling wave observed on the basilar membrane in an acoustically excited normally hearing cochlea. Preferably, the predicted electrode stimuli are based upon the instantaneous predicted amplitude of the electrode location.

Abstract: An implantable microphone device is provided. The device comprises a hermetically sealed housing (3) having an internal cavity (2). The internal cavity (2) has a microphone assembly arranged to receive sound waves originating from external the housing (3). The device further comprises a pressure sensor arrangement, arranged to detect and determine the differential pressure between the internal cavity (2) and the exterior of the housing (3). The determined differential pressure is used to determine a suitable transfer function to be applied to the output of the microphone assembly to produce a signal representative of the received sound waves.

Abstract: An electret microphone having reduced noise due to reduced leakage current is provided. The microphone includes a flexible diaphragm, and sensor member disposed in opposing, spaced relation to the diaphragm and comprising a semi-conductor channel. At least one electret surface, comprised of a dielectric material having a permanently-embedded static electric charge, is disposed on one of the diaphragm and the sensor member. In turn, the semi-conductor channel of the sensor member has an electrical conductivity dependent upon relative movement of the diaphragm and support member responsive to acoustic signals incident upon the diaphragm, wherein the channel provides an output signal indicative of the acoustic signals. The electret surface may be disposed on the diaphragm. Alternatively, the electret surface may be disposed on the sensor member in spaced, face-to-face relation to an electrically conductive surface located on the diaphragm.

Abstract: A universal implant for an implantable medical device, the universal implant including a plurality of functional components, having a plurality of hardware components disposed in a housing, and an auxiliary component interface disposed in a surface of the housing and configured to electrically connect any one of a plurality of auxiliary components to the hardware components. The universal implant further includes a determinator configured to identify one or more of the auxiliary components, select one or more of the functional components based on the identified auxiliary components, and adapt the selected functional components for operation with the identified auxiliary components.

Abstract: Electrode constructions comprise an inner wall structure with an electrode assembly disposed therein that includes a number of stimulation sites disposed at different locations along its length thereby forming an electrode array. An outer insulating layer is disposed over the electrode assembly and comprises a number of openings disposed therethrough at locations corresponding to the stimulation sites to thereby permit direct contact between the stimulation sites and an adjacent external object.

Abstract: An implantable apparatus and method are provided for use in conjunction with an implantable neurostimulation signal generator that provides an electrical stimulation signal to an active electrode. In auditory stimulation applications, the apparatus includes at least one anchor member having a distal end portion for directly contacting a patient's cranial bone and an electrically conductive portion extending from the distal end portion to a contact location proximal to the distal end portion. An electrical connection line may be electrically interconnected at a first end to the contact location of the anchor member and electrically interconnected at a second end to an implantable auditory neurostimulation signal generator to define a reference electrode. A bracket member may be mounted to a patient's cranial bone utilizing the anchor member, wherein an electrically conductive pathway extends from a first contact location to a second contact location of the bracket member.

Abstract: A method of processing audio signals for an auditory prosthesis is provided. The method includes a noise reduction step (22) and a later compression step (24). A gain control step is provided prior to the compression step (24). The gain control step operates so as to minimize the occurrence of signal compression in the compression step (24). An auditory prosthesis arranged to provide the method is also provided.

Abstract: An external component including a vibratory portion configured to vibrate in response to a sound signal to evoke a hearing percept via bone conduction and including a coupling portion configured to removably attach the external component to an outer surface of skin of a recipient of the hearing prosthesis while imparting deformation to the skin of the recipient at a location of the attachment, in a one-gravity environment, of an amount that is about equal to or equal to that which results from the external component having mass.

Abstract: A medical device, comprising first and second components coupled via a first wireless link; and a third component coupled to the first device via a second wireless link. The device implements a communication scheme in which transmissions via the second wireless link occur during a time period that is interleaved between periods including transmissions via the first link.

Abstract: A method of pre-processing a sound signal including music for an auditory prosthesis is provided. An input sound signal is received. The sound signal is processed using music pre-processing software to produce a music pre-processed signal. The music pre-processed signal is presented for further processing, so as to produce a corresponding stimuli signal.

Abstract: An implantable medical device configured to be implanted in a recipient. The implantable medical device includes an implantable assembly, wherein the exterior geometry of the implantable assembly is adapted to inhibit formation of a biofilm thereon after implantation in the recipient.

Abstract: An apparatus and method for determining stimulation channels for a stimulating device is provided. This method and apparatus may involve computing a set of weights for the plurality of stimulation channels of the stimulating hearing prosthesis. These weights may be determined by determining a transimpedance matrix for the stimulating hearing prosthesis where a diagonal of the transimpedance matrix is determined by extrapolation. A transadmittance matrix may then be computed for this transimpedance matrix. An error may then be computed base on positive off-diagonal terms of the transadmittance matrix. The apparatus and method may determine the weights for the stimulation channels by determining an adjustment to the diagonal of the transimpedance matrix that results in a computed error that does not exceed a specified criterion level.

Abstract: Embodiments of the present invention are generally directed to the use of a genetic algorithm for the purpose of providing progressive and adaptive auditory training (rehabilitation) to a recipient of a hearing prosthesis. In general, the genetic algorithm is used to adapt the training process to automatically increase the difficulty of the training based on recipient feedback and performance. That is, the genetic algorithm progressively removes perceivable sounds from the training process so as to generate groups of sounds that are difficult for a recipient to perceive.

Abstract: A method is provided for optimizing power consumption of a digital circuit which provides operational functionality based upon operating demands. The digital circuit is subject to a supply voltage level and a clock frequency. The method includes determining an acceptable delay value, from a plurality of predetermined acceptable delay values, for the digital circuit based upon current operating demands and the clock frequency. The supply voltage level and the clock frequency are applied to a delay monitor circuit. The delay experienced by the delay monitoring circuit is measured. The measured delay is compared with the determined acceptable delay value. Based on the outcome of the comparing step, the supply voltage level applied to the digital circuit is selectively adjusted. An arrangement for implementing the method is also provided.

Abstract: An implantable apparatus for delivering electrical stimuli to a user, the apparatus including at least a stimulator adapted to generate stimulation signals, an electrode array, said array including a plurality of electrodes for delivering said stimulation signals; and a plurality of release sites for pharmaceutical agents, said release sites being positioned at locations along said array, said release sites being controlled such that said agents can be operatively delivered at selected ones of said locations.

Abstract: Systems, methods, and devices are disclosed. An example sound processor is disclosed. The example sound processor includes a module configured to identify a feedback artifact in a current sample of an input spectral component by determining that a change in a signal level of an input spectral component is approximately equal to a predicted change. The predicted change may be based on one or more characteristics of an external feedback loop. Responsive to identifying the feedback artifact, the sound processor is further configured to apply a modification to a parameter used to process the input spectral component. The modification reduces a likelihood of including audible feedback in a processed input spectral component.

Abstract: Methods, systems, and devices for receiving a data signal and a power signal by a hearing prosthesis are disclosed. An input signal is received at a first unit of a hearing prosthesis. The first unit receives the input signal at a wired interface module that conforms to a standardized interface. The first unit identifies a data signal and a power signal included in the input signal. The first unit transfers at least a portion of the power signal to a second unit of the hearing prosthesis. The second unit is implanted in a body and is configured to stimulate an auditory organ, allowing a user to perceive at least a portion of a sound.