Abstract: A BTE prosthetic device for use in a medical system or prosthesis comprises a connector configured to mechanically attach an auxiliary device of the system to the BTE prosthetic device. The connector is electrically connected to a transceiver of the BTE prosthetic device. The connector operates as an electromagnetic antenna for transmitting and/or receiving signals between the BTE prosthetic and other components of the medical system.

Abstract: Presented herein are techniques for generating a stable reference clock for use by a short-range radio transceiver of an implantable component without the need for an X-tal oscillator within the implantable component itself. In accordance with certain techniques presented herein, the implantable component is in communication with a first external component via a closely-coupled link and in communication with a second external component via short-range radio link. The implantable component is configured to receive, from the first external component, signals via the closely-coupled link. The implantable component is configured to extract frequency information from these received signals and synchronize a carrier frequency of the short-range radio link to the frequency information extracted from the signals.

Abstract: Presented herein are implantable medical devices that comprise an implantable portion having a resonant tank circuit that is used to receive signals from one or more external devices. The resonant tank circuit is configured to operate at first and second resonant frequencies, where the first resonant frequency is optimized to exchange data with, and potentially receive operating power from, an external device, while the second resonant frequency is optimized to receive charging power. In certain embodiments, upon initiating operation of the implantable portion with at least one external device, the implantable portion is configured to force tune the resonant tank circuit to the first resonant frequency. That is, when the resonant tank circuit first begins receiving signals from an external device, the signals received at the resonant tank circuit are used to initially tune the resonant tank circuit to the first resonant frequency.

Abstract: An auditory prosthesis comprising an actuator for providing mechanical stimulation to a recipient. The auditory prosthesis comprises a measurement circuit for use in determining the resonance peak(s) of the actuator. In an embodiment, the measurement circuit measures the voltage drop across the actuator and/or current through the actuator during a frequency sweep of the operational frequencies of the actuator. These measured voltages and/or currents are then analyzed for discontinuities that are indicative of a resonance peak of the actuator. In another embodiment, rather than using a frequency sweep to measure voltages and/or currents across the actuator, the measurement circuit instead applies a voltage impulse to the actuator and then measure the voltage and/or current across the actuator for a period of time after application of the impulse. The measured voltages and/or currents are then analyzed to identify resonance peak(s) of the actuator.

Abstract: An auditory prosthesis can be powered by an on-board battery that is placed into a receptacle in the auditory prosthesis. When longer battery life is desired, a recipient can selectively utilize a discrete power supply to power the auditory prosthesis. The discrete power supply provides power to the auditory prosthesis and, in certain embodiments, has a longer life than the on-board battery. The discrete power supply includes an adapter having a form factor that mates with the battery receptacle on the auditory prosthesis.

Abstract: Embodiments presented herein are generally directed to techniques for the transfer of isochronous stimulation data over a standardized isochronous audio or data link between components of an implantable medical device system. More specifically, as described further below, a first component is configured to generate dynamic stimulation data based on one or more received sound signals. The first component is configured to obtain static configuration data and to encode the dynamic stimulation data and the static configuration data into a series of isochronous wireless packets. The first component is configured to transmit the series of wireless packets over an isochronous wireless channel to a second component of the implantable medical device system.

Abstract: Presented herein are low-power active bone conduction devices that comprise an actuator that is subcutaneously implanted within a recipient so as to deliver mechanical output forces to hard tissue of the recipient. The low-power active bone conduction devices include an energy recovery circuit configured to extract non-used energy from the actuator and to store the non-used energy for subsequent use by the actuator. The low-power active bone conduction devices may also include a multi-bit sigma-delta converter that operates in accordance with a scaled sigma-delta quantization threshold value to convert received signals representative of sound into actuator drive signals.

Abstract: A system that includes an implanted medical device such as an auditory prosthesis having a capacity to conduct communications on two channels to establish an association for communication with another electronic device. One of the channels is preferably a short range or near field channel, and the other channel is a broadcast channel. A method of asynchronous communication using both channels for establishing the association is also described.

Abstract: Certain medical devices, such as auditory prostheses, have an implantable portion and an external portion. The implantable portion and external portion each include a transmission/receiver coil that communicates signals between the two portions. The implanted coil is implanted about the ear canal while the external coil is disposed about the pinna or in the ear canal itself. The proximity of the two coils allows for signal transmission between the implantable and external portions.

Abstract: Presented herein are implantable medical devices that comprise an implantable portion having a resonant tank circuit that is used to receive signals from one or more external devices. The resonant tank circuit is configured to operate at first and second resonant frequencies, where the first resonant frequency is optimized to exchange data with, and potentially receive operating power from, an external device, while the second resonant frequency is optimized to receive charging power. In certain embodiments, upon initiating operation of the implantable portion with at least one external device, the implantable portion is configured to force tune the resonant tank circuit to the first resonant frequency. That is, when the resonant tank circuit first begins receiving signals from an external device, the signals received at the resonant tank circuit are used to initially tune the resonant tank circuit to the first resonant frequency.

Abstract: Embodiments presented herein are generally directed to techniques for the transfer of isochronous stimulation data over a standardized isochronous audio or data link between components of an implantable medical device system. More specifically, as described further below, a first component is configured to generate dynamic stimulation data based on one or more received sound signals. The first component is configured to obtain static configuration data and to encode the dynamic stimulation data and the static configuration data into a series of isochronous wireless packets. The first component is configured to transmit the series of wireless packets over an isochronous wireless channel to a second component of the implantable medical device system.

Abstract: Presented herein are low-power active bone conduction devices that comprise an actuator that is subcutaneously implanted within a recipient so as to deliver mechanical output forces to hard tissue of the recipient. The low-power active bone conduction devices include an energy recovery circuit configured to extract non-used energy from the actuator and to store the non-used energy for subsequent use by the actuator. The low-power active bone conduction devices may also include a multi-bit sigma-delta converter that operates in accordance with a scaled sigma-delta quantization threshold value to convert received signals representative of sound into actuator drive signals.

Abstract: Technologies disclosed herein can be used to test vibrating actuators, such as those found in auditory prostheses. An example test system includes a trigger signal generator that emits a trigger signal, a test frequency generator that operates in a test mode responsive to receiving a trigger signal, and a diagnostic tool comprising a vibration sensor.

Abstract: An auditory prosthesis comprising an actuator for providing mechanical stimulation to a recipient. The auditory prosthesis comprises a measurement circuit for use in determining the resonance peak(s) of the actuator. In an embodiment, the measurement circuit measures the voltage drop across the actuator and/or current through the actuator during a frequency sweep of the operational frequencies of the actuator. These measured voltages and/or currents are then analyzed for discontinuities that are indicative of a resonance peak of the actuator. In another embodiment, rather than using a frequency sweep to measure voltages and/or currents across the actuator, the measurement circuit instead applies a voltage impulse to the actuator and then measure the voltage and/or current across the actuator for a period of time after application of the impulse. The measured voltages and/or currents are then analyzed to identify resonance peak(s) of the actuator.

Abstract: Certain medical devices, such as auditory prostheses, have an implantable portion and an external portion. The implantable portion and external portion each include a transmission/receiver coil that communicates signals between the two portions. The implanted coil is implanted about the ear canal while the external coil is disposed about the pinna or in the ear canal itself. The proximity of the two coils allows for signal transmission between the implantable and external portions.

Abstract: Embodiments presented herein are generally directed to techniques for separately transferring power and data from an external device to an implantable component of a partially or fully implantable medical device. The separated power and data transfer techniques use a single external coil and a single implantable coil. The external coil is part of an external resonant circuit, while the implantable coil is part of an implantable resonant circuit. The external coil is configured to transcutaneously transfer power and data to the implantable coil using separate (different) power and data time slots. At least one of the external or internal resonant circuit is substantially more damped during the data time slot than during the power time slot.

Abstract: A system that includes an implanted medical device such as an auditory prosthesis having a capacity to conduct communications on two channels to establish an association for communication with another electronic device. One of the channels is preferably a short range or near field channel, and the other channel is a broadcast channel. A method of asynchronous communication using both channels for establishing the association is also described.

Abstract: The present invention is related to an implantable medical device. The medical device comprises an implantable component having a receiver unit; an external charging module having a power transmitter unit; and a data module having a data transmitter unit. The units are configured to establish a transcutaneous communication link over which data and power is transmitted on a single frequency channel via a time interleaving scheme comprising successive frames each divided into at least two time slots, and wherein one or more of the time slots in each frame is allocated to the data transmitter unit, and wherein one or more of the time slots in each frame is allocated to the power transmitter unit, and wherein data and power are transmitted by the transmitter units during their allotted time slots.

Abstract: An active medical device, including an input receiver configured to receive a frequency-varying input signal, and a functional component that reacts to the input signal and consumes power at a rate dependant on the frequency of portions of the input signal to which the functional component reacts, wherein the active medical device is configured to adjust one or more portions of the input signal corresponding to portions of the input signal where the functional component consumes power at a rate that is greater than that of other portions of the input signal.

Abstract: Presented herein are low-power active bone conduction devices that comprise an actuator that is subcutaneously implanted within a recipient so as to deliver mechanical output forces to hard tissue of the recipient. The low-power active bone conduction devices include an energy recovery circuit configured to extract non-used energy from the actuator and to store the non-used energy for subsequent use by the actuator. The low-power active bone conduction devices may also include a multi-bit sigma-delta converter that operates in accordance with a scaled sigma-delta quantization threshold value to convert received signals representative of sound into actuator drive signals.