Abstract: Presented herein are stimulation techniques for implantable tissue-stimulating systems. The stimulation techniques generate and deliver sets of micro-charge pulses to a recipient. The micro-charge pulses within a set collectively cause the firing of a recipient's nerve cell(s).

Abstract: Presented herein are techniques for protecting an implantable component of a medical device from the buildup of excessive heat following a charging process. In one embodiment, the implantable component includes a resonant tank circuit that includes an implantable coil that receives power from the external charging device via an inductive link. The implantable component includes a rechargeable battery that is electrically connected to the resonant tank circuit and that can be recharged using the power received from the external charging device. A controller in the implantable component is configured to determine when charging of the rechargeable battery should be terminated and, in response, detune the resonant tank circuit in accordance with a predetermined pattern to signal to the external charging device that charging of the rechargeable battery should be terminated.

Abstract: A cochlear implant or other auditory prosthesis utilizes an external portion worn on a recipient's head and an internal portion implanted therein. Both portions include an associated coil that transmits a signal between the two portions. The external coil has a form factor substantially similar to the implantable coil. This form factor allows the external portion to be manufactured with a smaller footprint, since components that may otherwise interfere with signal transmission (e.g., batteries) may be installed closer to the external coil.

Abstract: Presented herein are techniques for protecting an implantable component of a medical device from the buildup of excessive heat following a charging process. In one embodiment, the implantable component includes a resonant tank circuit that includes an implantable coil that receives power from the external charging device via an inductive link. The implantable component includes a rechargeable battery that is electrically connected to the resonant tank circuit and that can be recharged using the power received from the external charging device. A controller in the implantable component is configured to determine when charging of the rechargeable battery should be terminated and, in response, detune the resonant tank circuit in accordance with a predetermined pattern to signal to the external charging device that charging of the rechargeable battery should be terminated.

Abstract: An inductance communication coil, including a conductor having at least one conductive turn, wherein a width of the conductor is wider at a first location relative to that at a second location. The conductor can be made out of metal. In some embodiments, the first location and the second location are on the same turn. In some embodiments, the conductor includes a plurality of turns, wherein the first location is at a first turn and the second location is at a second turn.

Abstract: A coil, such as, by way of example, an inductance communication coil, that includes a conductor including a first portion extending in a first level and a second portion extending in a second level, wherein the conductor includes a third portion located on a different level than that of the second portion, wherein an electrical path of the conductor is such that the second portion is located between the first portion and the third portion.

Abstract: Presented herein are stimulation techniques for implantable tissue-stimulating systems. The stimulation techniques generate and deliver sets of micro-charge pulses to a recipient. The micro-charge pulses within a set collectively cause the firing of a recipient's nerve cell(s).

Abstract: Embodiments presented herein are generally directed to inductive charging techniques in an implantable medical device system comprising an inductive charger and an external component. The external component includes a rechargeable battery and an inductive coil that is configured to form an inductive charging link with a charging coil in the inductive charger to receive power signals from the inductive charger. A voltage increasing converter in the external component is configured to step-up a voltage of the power signals received from the inductive charger for use in recharging the rechargeable battery.

Abstract: Cables are utilized to both charge components of an auditory prosthesis and transmit data signals between components of the auditory prosthesis. The cable is configured so as to enable a recipient to charge her device without having to lose the hearing function of the auditory prosthesis. Connectors can be utilized to connect to the various components of the auditory prosthesis, as well as to a discrete power source. The cable can be connected directly to each component of the auditory prosthesis or can be connected via cables that are already a part of the auditory prosthesis.

Abstract: Systems and apparatuses are used to transmit data between external and internal portions of auditory prostheses or other medical devices. The external portion of the auditory prosthesis includes a magnet and an implanted coil that provides stimulation to the device recipient. A shaped shield material can be placed between the external coil and the sound processing hardware to improve efficiency and effectiveness between the external coil and implanted coil. Adverse effects on tuning frequencies can be reduced by disposing the shield material away from the magnet.

Abstract: A cochlear implant or other auditory prosthesis utilizes an external portion worn on a recipient's head and an internal portion implanted therein. Both portions include an associated coil that transmits a signal between the two portions. The external coil has a form factor substantially similar to the implantable coil. This form factor allows the external portion to be manufactured with a smaller footprint, since components that may otherwise interfere with signal transmission (e.g., batteries) may be installed closer to the external coil.

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.