Abstract: An interface system for semi-implantable and fully implantable hearing aid devices that provides direct delivery of audio input from external wireline and wireless sources to the speech processor of the hearing aid. The speech processor of the hearing aid processes the audio inputs to produce a processed signal for a transducer portion of the hearing aid that is implanted in a hearing impaired individual. In a semi-implantable hearing aid, the interface system could be included in the external portion of the hearing aid or be included in an audio input device that replaces the external portion of the hearing aid when sound from a wireless or wireline source is desired. In a fully implantable hearing aid, an audio input device including the interface system is provided for use when sound from a wireless or wireline source is desired.

Abstract: An at least partially implantable hearing system for rehabilitation of a hearing disorder, comprising at least one acoustic sensor for picking up an acoustic signal and converting it into an electrical audio sensor signal; an electronic signal processing unit for audio signal processing and amplification, the signal processing unit including an electronic driver arrangement; an electrical power supply unit which supplies individual components of the system with energy; and at least one electromechanical output transducer driven by the electronic driver arrangement and having a mechanical output impedance, said transducer being provided with an active electromechanical element and an output member for stimulating, via a passive coupling element, an ossicle of a middle ear ossicular chain, which chain has a natural capability for vibratory movement; wherein a switchable clutch arrangement is disposed between the active electromechanical element of the transducer and the passive coupling element, and wherein in

Abstract: A modulation process with a fully suppressed carrier and input preprocessor filtering to produce an encoded output; for amplitude modulation (AM) and audio speech preprocessor filtering, intelligible subjective sound is produced when the encoded signal is demodulated using the RF Hearing Effect. Suitable forms of carrier suppressed modulation include single sideband (SSB) and carrier suppressed amplitude modulation (CSAM), with both sidebands present.

Abstract: A method is provided, the method comprising controlling an implantable medical device using a controller using a pre-emptive real-time operating system (RTOS) having a scheduling mechanism utilizing a priority inheritance protocol, the controller having a firmware architecture allowing at least one of modular feature design, modular feature implementation, extensible feature design and extensible feature implementation. The device also comprises analyzing the pre-emptive real-time operating system (RTOS) using rate monotonic analysis, providing an interface with downloadable software for the implantable medical device and backing up at least some of the downloadable software using a non-volatile memory device, protecting the at least some of the downloadable software from a reset of the implantable medical device.

Abstract: A hearing aid comprised of conventional cochlear implant electronics implanted in the middle ear and coupled to an actuator configured to mechanically vibrate the middle ear ossicles. The implant electronics, typically used for driving an electrode array implanted in the cochlea, is used instead to supply electric drive signals to the actuator for mechanically vibrating the ossicles.

Abstract: An implantable energy storage system for a medical implant, which is provided with a rechargeable storage for electric energy and a unit for controlling the charging process. The system includes a monitoring unit which is independent of the control unit and which senses the storage voltage independently of the control unit and is designed such that it assumes control of the charging path when the sensed storage voltage lies outside a predetermined range. Furthermore, a corresponding process for operating the implantable energy storage system is provided.

Abstract: A moisture-resistant, wideband microphone subassembly for a Behind-The-Ear (BTE) hearing device, provides a barrier to perspiration and rain, while maintaining a good frequency response. The microphone subassembly is contained in the case of the BTE hearing device and comprises a microphone, a boot, and a moisture-resistant membrane. The boot structurally supports the microphone, provides a moisture seal around the microphone case, and provides the microphone with isolation from vibrations in the case of the BTE hearing device. The membrane resists the passage of moisture, while providing an acoustic window permitting sound waves to reach the microphone. In one embodiment high compliance washers sandwich the membrane to improve frequency response. A preferred embodiment provides a substantially flat acoustic frequency response to beyond 10 KHz.

Abstract: A neural prosthetic device for reducing or eliminating the effects of tinnitus is inserted into a tinnitus patient's primary auditory cortex (or thalamus). The prosthetic device includes a stimulation device for outputting processed electrical signals and an electrode arranged in the primary auditory cortex having a plurality of electrical contacts. Each of the plurality of electrical contacts independently outputs electrical discharges in accordance with the electrical signals. In another embodiment, a catheter is inserted into the tinnitus patient's primary auditory cortex or thalamus. The catheter microinfuses drugs which suppress or eliminate abnormal neural activity into disperse geometric locations in the cortex or thalamus, thereby reducing or eliminating the effects of the patient's tinnitus.

Abstract: A modulation process with a fully suppressed carrier and input preprocessor filtering to produce an encoded output; for amplitude modulation (AM) and audio speech preprocessor filtering, intelligible subjective sound is produced when the encoded signal is demodulated using the RF Hearing Effect. Suitable forms of carrier suppressed modulation include single sideband (SSB) and carrier suppressed amplitude modulation (CSAM), with both sidebands present.

Abstract: Stimulating one or more vestibulocochlear nerves or cochlea or cochlear regions will treat, prevent and control auditory hallucinations.

Abstract: A transcanal, transtympanic cochlear implant system for implantation comprising a molded insert for removable positioning in the auditory canal of the human ear and an insulated receiver coil, preferably in a generally circular or looped form, where the receiver coil receives electromagnetic signals, in a first embodiment, or radio frequency signals, in a second embodiment, through inductive coupling to a solenoid coil within the molded insert.

Abstract: The present invention relates to a device for picking up biological electrical signals, and more precisely auditory evoked potentials generated by acoustic and/or electrical and/or mechanical stimulation of the cochlea, or of a portion of the auditory system in man or animal. The device for measuring or picking up auditory evoked potentials is surgically implantable in the temporo-occipital area and comprises at least two extracochlear pickup electrodes connected to the inputs of a differential amplifier.

Abstract: A system and method for application of pseudospontaneous neural stimulation is provided that can generate stochastic independent activity across an excited nerve or neural population without an additional disadvantageous sensations. High rate pulse trains, for example, can produce random spike patterns in auditory nerve fibers that are statistically similar to those produced by spontaneous activity in the normal ear. This activity is called “pseudospontaneous activity”. Varying rates of pseudospontaneous activity can be created by varying the intensity of a fixed amplitude, high rate pulse train stimulus, e.g., 5000 pps. A method and apparatus for diagnosing treatment for tinnitus with neural prosthetic devices according to the present invention that can use, for example, physiological responses to pseudospontaneous activity in an auditory nerve prior to the implementation of the neural prosthetic.

Abstract: The invention describes an adaptive, sensory-motor encoder for a visual prosthesis or for an acoustic prosthesis and equipped with a central control unit for signal processing functions, monitoring functions, control functions and external intervention functions as well as with a group of adaptive spatio-temporal filters for the conversion of sensor signals into stimulation impulse sequences, whereby a bi-directional interface is provided for coupling the encoder with an implantable microstructure (2) for stimulation of nerve or glial tissue on the one hand, and on the other hand for function monitoring of brain function.

Abstract: Partially or fully implantable hearing aid for rehabilitation of an inner ear hearing disorder, with a microphone (10) which delivers an audio signal, an electronic signal processing and amplification unit (40, 50, 80, 140, 141) which is located in an audio signal-processing electronic hearing aid path, an implantable electromechanical output converter (20) and a unit (60) for power supply of the implant. The hearing aid is provided with an electronic module (90, 140, 141) for rehabilitation of tinnitus and it generates the signals necessary for a tinnitus masking or noiser function and feeds them into the audio signal processing path of the hearing implant.

Abstract: The invention discloses a programmable implantable hearing aid including built-in electronics being in wireless communications with a hand-held programmer. The programmer transmits digital code signals of the type including RF, infrared and ultrasonic, based on selected parameter settings. A receiver accepts the signals for transmission to an input transducer in the middle ear. The input transducer collects the middle ear's response to the signals and transmits it to a circuit in the implanted hearing aid. The circuit searches for specific programming patterns and decodes the signals to effectuate the desired adjustment in the hearing aid. The conditioned signals are then transferred to an output transducer to operate the device at the adjusted signal level and condition. The invention enables both a patient and doctor to make unlimited number of adjustments in the implanted hearing aid without invasive surgery.

Abstract: A hearing assistance system includes multiple middle ear transducers for sensing vibrations of an ossicle or other auditory element. The hearing assistance system is configured to accommodate an unknown or variable direction of the vibration. Two transducers are arranged to transduce nonidentical directional components of the vibration into electrical signals which are then combined. The combined electrical signal is approximately independent of the direction of the vibration, or has improved frequency response, or has an amplitude that is approximately independent of the direction of the vibration. The combined electrical signal may result from a square root of sum-of-squares, sum of individually filtered signals, differentiation, or other techniques. The hearing assistance system analogously accommodates three dimensional variability of the direction of vibration using three middle ear transducers.

Abstract: A system and method for application of pseudospontaneous neural stimulation is provided that can generate stochastic independent activity across an excited nerve or neural population without an additional disadvantageous sensations. High rate pulse trains, for example, can produce random spike patterns in auditory nerve fibers that are statistically similar to those produced by spontaneous activity in the normal ear. This activity is called “pseudospontaneous activity”. Varying rates of pseudospontaneous activity can be created by varying the intensity of a fixed amplitude, high rate pulse train stimulus, e.g., 5000 pps. The pseudospontaneous activity can further desynchronize the nerve fiber population as a treatment for tinnitus but if indiscriminately applied can generate potentially uncomfortable biological and somatosensory sensations over intervals of time.

Abstract: A universal strategy selector (USS) for use with a multichannel cochlear prosthesis includes: (a) a processor, or equivalent; (b) a selector; and (c) a display. The multichannel cochlear prosthesis is characterized by multiple stimulation channels through which a specific pattern of electrical stimulation, modulated by acoustic signals, and in accordance with a selected speech processing strategy, may be spatiotemporal applied to a patients cochlea in order to yield speech intelligibility. The processor of the USS includes appropriate processing means coupled to the multichannel cochlear prosthesis for defining one of a plurality of speech processing strategies for use by the multichannel cochlear prosthesis. In one embodiment, the processing means is realized using a personal computer (PC) programmed with appropriate software. The speech processing strategy that may be selected by the USS may be selected from a multiplicity of speech processing strategies.

Abstract: A hearing assistance system senses sound vibrations of an auditory element in the middle ear and provides a stimulus to an auditory sensory element. The vibrations are received through the tympanic membrane, and sensed at the tympanic membrane, malleus, incus, or other auditory element. A capacitive sensor is mechanically or magnetically coupled to a vibrating auditory element, such as the malleus, and time-varying capacitance values resulting from the vibrations are detected. One embodiment allows pivotable mechanical coupling of the capacitive sensor to at least one of the auditory element and a carrier secured within the middle ear. An resulting electrical output signal is provided to the output stimulator for assisting hearing.

Abstract: A hearing assistance system includes multiple middle ear transducers for sensing vibrations of an ossicle or other auditory element. The hearing assistance system is configured to accommodate an unknown or variable direction of the vibration. Two transducers are arranged to transduce nonidentical directional components of the vibration into electrical signals which are then combined. The combined electrical signal is approximately independent of the direction of the vibration, or has improved frequency response, or has an amplitude that is approximately independent of the direction of the vibration. The combined electrical signal may result from a square root of sum-of-squares, sum of individually filtered signals, differentiation, or other techniques. The hearing assistance system analogously accommodates three dimensional variability of the direction of vibration using three middle ear transducers.

Abstract: An at least partially implantable system for rehabilitation of a hearing disorder with an arrangement for processing and/or generation of signals is provided including an implantable processor arrangement with control logic which operates according to an operating program and an implantable storage arrangement for storage of the operating program and of operating parameters. A wireless telemetry unit is provided for data transmission between the implantable part of the system and an external unit. The system also includes a power supply arrangement which supplies individual components of the system with current and a rewritable implantable storage arrangement assigned to the processor arrangement for holding and reproducing the operating program and the operating parameters. At least a part of the operating program and/or of the operating parameters can be modified and/or replaced by data transmitted from the external unit via the telemetry unit.

Abstract: A hearing assistance system senses sound vibrations of an auditory element in the middle ear and provides a stimulus to an auditory sensory element. The vibrations are received through the tympanic membrane, and sensed at the tympanic membrane, malleus, incus, or other auditory element. An electromagnetic sensor includes receiving and reference elements, e.g. a permanent magnet and a coil, having a time-varying magnetic flux linkage due to the vibrations. The magnet and coil are pivotably coupled to an auditory element and a carrier, or vice-versa, for self-alignment. A resulting electrical signal on the coil is processed, then provided to an output stimulator for mechanical or electrical stimulation of the cochlea.

Abstract: A floating mass transducer for improving hearing in a hearing impaired person is provided. The floating mass transducer (100) may be implanted or mounted externally for producing vibrations in a vibratory structure of an ear. In an exemplary embodiment, the floating mass transducer comprises a magnet assembly (12) and a coil (14) secured inside a housing (10) which is fixed to an ossicle of a middle ear. The coil is more rigidly secured to the housing than the magnet. The magnet assembly and coil are configured such that conducting alternating electrical current through the coil results in vibration of the magnet assembly and coil relative to one another. The vibration is caused by the interaction of the magnetic fields of the magnet assembly and coil. Because the coil is more rigidly secured to the housing than the magnet assembly, the vibrations of the coil cause the housing to vibrate. The vibrations of the housing are conducted to the oval window of the ear via the ossicles.

Abstract: A hearing assistance system senses sound vibrations of an auditory element in the middle ear and provides a stimulus to an auditory sensory element. The vibrations are received through the tympanic membrane, and sensed at the tympanic membrane, malleus, incus, or other auditory element. A capacitive sensor is mechanically or magnetically coupled to a vibrating auditory element, such as the malleus, and time-varying capacitance values resulting from the vibrations are detected. One embodiment allows pivotable mechanical coupling of the capacitive sensor to at least one of the auditory element and a carrier secured within the middle ear. A resulting electrical output signal is provided to the output stimulator for assisting hearing.

Abstract: An implantable receiver (12) is powered and controlled by an external (not-implanted) transmitter (14) when a transmitter coil (22) is properly aligned with a receiver coil (20). No magnets are used in either the transmitter or receiver to achieve and maintain the needed alignment. Rather, a special set of implant tools (50) are used to assure that alignment is achieved and maintained between the implantable receiver (12) and external transmitter (14) when the implant operation is carried out. A preferred embodiment of the invention provides a magnetless implantable cochlear stimulator (ICS) (40) and a corresponding magnetless headpiece (30) worn behind the ear.

Abstract: A device to be worn in the ear of a subject provides a direct vibrational drive to the tympanic membrane through a vibrationally conductive assembly which couples vibrations from a vibratory transducer positioned within the ear canal proximal to the tympanic membrane. In one embodiment of the invention, the device is a hearing aid positioned inconspicuously deep within the ear canal. The vibrationally conductive assembly is removably attached to the umbo area of the tympanic membrane. The vibrationally conductive assembly is designed to conduct vibrations in the audible frequency range while absorbing static forces caused by device placement and ear canal movement attributable to jaw movements of the wearer, including speaking, eating, drinking, chewing, yawning, and so forth.

Abstract: A signal processing apparatus and method for neural stimulation is provided that can generate stochastic independent activity across an excited nerve or neural population. High rate pulse trains, for example, can produce random spike patterns in auditory nerve fibers that are statistically similar to those produced by spontaneous activity in the normal ear. This activity is called "pseudospontaneous activity". Varying rates of pseudospontaneous activity can be created by varying the intensity of a fixed amplitude, high rate pulse train stimulus, e.g., 5000 pps. The pseudospontaneous activity can eliminate a major difference between acoustic- and electrical-derived hearing percepts. The pseudospontaneous activity can further desynchronize the nerve fiber population as a treatment for tinnitus.

Abstract: A device for diagnosing and treating hearing disorders including a supersonic transducer which has a resonance frequency in the supersonic range. The transducer includes a piezoelectric ceramic tube which is compressed between a head mass and an inertial mass. A tensioning rod extends between the masses and is threadedly engaged with a nut which tensions the rod to adjust the compression on the ceramic tube. A tuning circuit can be used to increase the band width at resonance.

Abstract: A hearing assistance system senses sound vibrations of an auditory element in the middle ear and provides a stimulus to an auditory sensory element. The vibrations are received through the tympanic membrane, and sensed at the tympanic membrane, malleus, incus, or other auditory element. An electromagnetic sensor includes receiving and reference elements, e.g. a permanent magnet and a coil, having a time-varying magnetic flux linkage due to the vibrations. The magnet and coil are pivotably coupled to an auditory element and a carrier, or vice-versa, for self-alignment. A resulting electrical signal on the coil is processed, then provided to an output stimulator for mechanical or electrical stimulation of the cochlea.

Abstract: A system for providing transdermal communication with, and power to, a subcutaneously implanted device, for example the stimulator unit of a cochlear implant, by means of pairs of orthogonally wound, inductively coupled coils. The system provides a compact coil arrangement particularly suited to behind the ear and in-the ear multi-channel cochlear implants.

Abstract: A hearing assistance system senses sound vibrations of an auditory element in the middle ear and provides a stimulus to an auditory sensory element. The vibrations are received through the tympanic membrane, and sensed at the tympanic membrane, malleus, incus, or other auditory element. A capacitive sensor is mechanically or magnetically coupled to a vibrating auditory element, such as the malleus, and time-varying capacitance values resulting from the vibrations are detected. One embodiment allows pivotable mechanical coupling of the capacitive sensor to at least one of the auditory element and a carrier secured within the middle ear. A resulting electrical output signal is provided to the output stimulator for assisting hearing.

Abstract: A cochlea stimulation system includes a patient wearable system comprising an externally wearable signal processor (WP) and a headpiece in electronic communication with an implanted cochlear stimulator (ICS). The ICS comprises eight output stages each having two electrically isolated capacitor-coupled electrodes, designated "A" and "B", circuits for monitoring the voltages on these electrodes, and circuits for both transmitting status information to and receiving control information from the WP. Based upon information received from the WP, a processor within the ICS can control both the frequency and the widths of the output stimulation pulses applied to the electrodes and may select which electrodes to monitor. The ICS receives power and data signals telemetrically through the skin from the WP. To save power, the ICS may be "powered down" by the WP based upon the absence of audio information or "powered up" if audio is present.

Abstract: A method and apparatus transduces between mechanical and electrical signals within a middle ear to improve hearing. An electromechanical transducer film, preferably polyvinylidene fluoride (PVDF), is carried by a mount secured to the middle ear. The film is constrained by the mount, or by the mount and an auditory element. The invention includes substantially straight, bow-shaped, hoop-shaped, and bi-element transducer film embodiments. The film transduces between mechanical vibrations of an auditory element, such as the malleus or stapes, and electrical signals for use with an electronics unit of a partial middle ear implantable (P-MEI) or total middle ear implantable (T-MEI) hearing aid.

Abstract: A cochlear implant system including primary and secondary coils of wire for transmitting electromagnetic energy between the primary and secondary coils, wherein at least one of the primary and secondary coils are wound with turns of wire that are distributed radially and not concentrated at a single circumference so as to enhance the magnetic coupling coefficient of the primary and secondary coil systems.

Abstract: An implantable hearing aid system for the middle ear utilizes pairs of permanent magnets to engage transducers with auditory elements in a middle ear. At least one transducer is supported within the middle ear cavity by a support. A transducer is magnetically-engaged with a malleus in one embodiment and another transducer is magnetically-engaged with a stapes in other embodiments. When using two contactless transducers, a permanent magnet is attached to each transducer. A permanent magnet is also attached to the malleus and to the stapes. The permanent magnet on each transducer is situated such that its polarity acts in repulsion to the permanent magnet on the adjacent auditory element.

Abstract: An implantable cochlear stimulator (ICS) has eight output stages (212), each having a current source (212B) connected to a pair of electrodes, designated "A" and "B", through respective output coupling capacitors and an electrode switching matrix (212C). An indifferent electrode is connected to each output stage by way of an indifferent electrode switch (212D). The current source generates a precise stimulation current as a function of an analog control voltage. The analog control voltage, in turn, is generated by a logarithmic D/A converter. The D/A converter serially converts data words, received in a data frame from an external source, to respective analog control voltages that are applied sequentially to the current sources of each output stage. An output mode register (208) controls the switching matrix of each stage, as well as the indifferent electrode switch, to configure the electrodes for a desired stimulation configuration, e.g.

Abstract: A method for evaluating the electromotility of hair cells within the cochlea of a mammalian ear by providing an electrode in proximate relation with the round window and applying electricity therethrough in order to electrically excite hair cells within the cochlea to produce electrically-evoked otoacoustic emissions therefrom. The electrically-evoked otoacoustic emissions further excite the internal structure of the cochlea which produces vibrations at the oval window that act through the bones of the middle ear to drive the tympanic membrane, producing corresponding acoustic sounds in the ear canal. The resulting acoustic sounds in the ear canal are subsequently detected with a microphone where they are later measured and characterized via readily available signal processing techniques.

Abstract: A method and apparatus transduces between mechanical and electrical signals within a middle ear to improve hearing. An electromechanical transducer film, preferably polyvinylidene fluoride (PVDF), is carried by a mount secured to the middle ear. The film is constrained by the mount, or by the mount and an auditory element. The apparatus includes substantially straight, bow-shaped, hoop-shaped, and bi-element transducer film embodiments. The film transduces between mechanical vibrations of an auditory element, such as the malleus or stapes, and electrical signals for use with an electronics unit of a partial middle ear implantable (P-MEI) or total middle ear implantable (T-MEI) hearing aid.

Abstract: A system is disclosed for enabling telemetry from an auditory prosthesis, illustratively a cochlear prosthesis. An electrode array 10 is used both for delivering electrical stimuli, and for sensing evoked potentials. Preferably a delay is provided between stimulus and measurement, and the sensing electrodes are distinct from the stimulus electrodes.

Abstract: An implanted device such as a cochlear implant system includes a housing containing stimulating pulse generating circuitry, and a plurality of electrodes external of the housing and receiving the pulses. Between the pulses, parasitic voltages may build up between the electrodes. In order to control the inrush current due to these parasitic voltages, multi-position switches are provided which selectively couple the electrodes to resistors selected to dissipate the voltages at a preselected maximum current to protect the body organs.

Abstract: A low-cost, four-channel cochlear stimulation system utilizes a completely passive, implantable receiver/electrode array that is inductively coupled to an external wearable processor. The receiver/electrode array is formed in a silicone rubber carrier adapted to be implanted in a deaf patient. At one end of the receiver/electrode array, positioned subcutaneously near the surface of skin above the ear, four receiving coils are arranged in an appropriate pattern. Such receiving coils are held within an hermetically-sealed titanium case. At the other end of the receiver/electrode array, which may be pre-formed in a spiral to match the basal turn of the cochlea, and which is inserted in the cochlea, four ball electrodes are spaced apart along an inner radius of the spiral. Each electrode is electrically connected to a respective receiving coil. Each receiving coil is also electrically connected to a reference electrode typically located near the receiver-coil end of the array.

Abstract: A data link and protocol for a subcutaneous, tissue stimulating device. While stimulation is taking place, under control of pulses whose durations in a data frame determine the stimulation pulse widths, data is actually transmitted and processed for determining the parameters of the next stimulation. Thus transmission of data occurs simultaneously with stimulation. Data is represented by sequences which have more 1s than 0s, with each 1 being represent by a number of successive RF cycles and a single 0 by the absence of a number of RF cycles. In this way a duty cycle of 75% can be achieved so that required power is transferred to the implant. Variations in link condition, e.g., degree of ringing, are accommodated by means of offset tuning the transcutaneous transmit and receive coils. This ensures that the oscillating signal in the receive circuit that persists during the transmission of a 0 becomes out-of-phase with the RF transmission that is received for the next 1.

Abstract: A method for implanting a neural prosthetic into a target zone of a patient's brain for reducing or eliminating the effects of tinnitus. The prosthetic includes a stimulation device for outputting processed electrical signals and an electrode which is arranged in the target zone having a plurality of electrical contacts. Each of the plurality of electrical contacts independently outputs electrical discharges in accordance with the electrical signals.

Abstract: A neural prosthetic device for reducing or eliminating the effects of tinnitus is inserted into a tinnitus patient's primary auditory cortex (or thalamus). The prosthetic device includes a stimulation device for outputting processed electrical signals and an electrode arranged in the primary auditory cortex having a plurality of electrical contacts. Each of the plurality of electrical contacts independently outputs electrical discharges in accordance with the electrical signals. In another embodiment, a catheter is inserted into the tinnitus patient's primary auditory cortex or thalamus. The catheter microinfuses drugs which suppress or eliminate abnormal neural activity into disperse geometric locations in the cortex or thalamus, thereby reducing or eliminating the effects of the patient's tinnitus.

Abstract: A floating mass transducer for improving hearing in a hearing impaired person is provided. The floating mass transducer (100) may be implanted or mounted externally for producing vibrations in a vibratory structure of an ear. In an exemplary embodiment, the floating mass transducer comprises a magnet assembly (12) and a coil (14) secured inside a housing (10) which is fixed to an ossicle of a middle ear. The coil is more rigidly secured to the housing than the magnet. The magnet assembly and coil are configured such that conducting alternating electrical current through the coil results in vibration of the magnet assembly and coil relative to one another. The vibration is caused by the interaction of the magnetic fields of the magnet assembly and coil. Because the coil is more rigidly secured to the housing than the magnet assembly, the vibrations of the coil cause the housing to vibrate. The vibrations of the housing are conducted to the oval window of the ear via the ossicles.

Abstract: A multichannel stimulation system includes a plurality of implantable microminiature stimulators (microstimulators), each being connected to a respective implanted electrode or electrode array. Each microstimulator is selectively operable as controlled by an external (non-implanted) control unit. The electrode or electrode array is implanted so as to contact nerves and/or tissue that is to be stimulated. Operating power is inductively coupled from the control unit to the microstimulators. An information signal is also coupled to the microstimulators to control which of the microstimulators is to be activated to provide a stimulation pulse to its respective electrode. In one embodiment, the invention provides a cochlear prosthesis with an intracochlear electrode array being implanted within the human cochlea, and with selected electrodes of the array being connected to individual ones of the plurality of microstimulators.

Abstract: An external wearable processor (WP) of a cochlear stimulating system transmits a data signal to an implanted cochlear stimulator (ICS). The ICS is controlled through the data signal so that cochlear stimulation is provided by the ICS only after a determination is made that the WP is in proper signal contact therewith, and that the ICS is functioning properly. The ICS extracts a raw power signal from the data signal and generates different operating voltages from the extracted raw power signal. A detector generates a power bad signal whenever one of the operating voltages is less than a reference voltage. The ICS also detects and generates a carrier detect signal when the data signal is being received. Clock signals are generated within the ICS, and a phase locked loop (PLL) lock signal is generated when the clock signals are phase locked to the data signal. ICS circuitry further checks the parity of the incoming data signal and generates a parity alarm signal whenever a parity error is detected.

Abstract: An implantable cochlear stimulator (ICS) has eight output stages (212), each having a programmable current source (212B) connected to a pair of electrodes, designated "A" and "B", through respective output coupling capacitors and an electrode switching matrix (212C). An indifferent electrode is connected to each output stage by way of an indifferent electrode switch (212D). An output mode register (208) controls the switching matrix of each stage, as well as the indifferent electrode switch, to configure the electrodes for: (1) bipolar stimulation (current flow between the pair of electrodes of the output stage), (2) monopolar A stimulation (current flow between the "A" electrode of the output stage and the indifferent electrode), (3) monopolar B stimulation (current flow between the "B" electrode of the output stage and the indifferent electrode), or (4) multipolar stimulation (current flow between the "A" or "B" electrode of one output stage and the "A" or "B" electrode of another output stage).

Abstract: A tissue stimulating system includes an external transmitter for transmitting a data signal to an implanted stimulator. The implanted stimulator includes a processor for generating stimulation signals for application to a plurality of tissue stimulating electrodes through respective isolated output channels. The implanted stimulator also includes a power supply that extracts a raw power signal from the data signal. A voltage downconverter generates at least four separate voltages from the extracted raw power signal by alternately connecting at least four capacitors in series across the raw power signal, thereby providing at least four output voltages, and then connecting the capacitors in parallel to transfer the charge stored thereon to a storage capacitor, which serves as the power source for portions of the stimulator.