Biomedical implant with high speed, low power two-way telemetry
First Claim
1. A two-way telemetry system for a biomedical implantable device including means for providing an externally generated carrier signal, comprisingan implantable enclosure,a telemetry coil tuned to said carrier signal and mounted within said enclosure,a low impedance shunt circuit connected across said tuned coil including semiconductor means for modulating the impedance of said shunt circuit in accordance with a digital information signal to alter the phase and amplitude of a signal that is reradiated by said tuned coil in the presence of said externally generated magnetic carrier signal at said carrier frequency,detector means coupled to said telemetry coil for producing an output related to each successive cycle of said carrier signal, andtelemetry timing means responsive to said detector means output for producing said digital information signal to said shunt circuit in a predetermined synchronized relationship with the cycles of said carrier signal,said telemetry timing means including means for counting the number of cycles of said carrier signal and for establishing a relationship between the data of said digital information signal and the number of cycles of said carrier signal,said timing means further including means for actuating said shunt circuit in a first condition for a predetermined number of cycles of said carrier signal and in a second condition for a predetermined different second number of cycles of said carrier signal.
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Accused Products
Abstract
For inbound data transmission a carrier signal is gated by the external programmer to transmit bursts of discrete numbers of cycles. The carrier is picked up by an implanted telemetry coil. The bursts are amplified and decoded by "missing pulse" detection. Outbound telemetry is synchronized with the external constant carrier in a similar manner by loading the coil for discrete numbers of cycles. In the preferred embodiment, within an eight cycle bit period, two cycles of 64 kHz carrier represent "0" while a six cycle burst represents "1", to achieve a two-way data transmission rate of 8000 bits per second.
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Citations
18 Claims
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1. A two-way telemetry system for a biomedical implantable device including means for providing an externally generated carrier signal, comprising
an implantable enclosure, a telemetry coil tuned to said carrier signal and mounted within said enclosure, a low impedance shunt circuit connected across said tuned coil including semiconductor means for modulating the impedance of said shunt circuit in accordance with a digital information signal to alter the phase and amplitude of a signal that is reradiated by said tuned coil in the presence of said externally generated magnetic carrier signal at said carrier frequency, detector means coupled to said telemetry coil for producing an output related to each successive cycle of said carrier signal, and telemetry timing means responsive to said detector means output for producing said digital information signal to said shunt circuit in a predetermined synchronized relationship with the cycles of said carrier signal, said telemetry timing means including means for counting the number of cycles of said carrier signal and for establishing a relationship between the data of said digital information signal and the number of cycles of said carrier signal, said timing means further including means for actuating said shunt circuit in a first condition for a predetermined number of cycles of said carrier signal and in a second condition for a predetermined different second number of cycles of said carrier signal.
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11. An external programming data transmitter for a biomedical implant, comprising
oscillator means for generating a continuous wave carrier signal of constant frequency, transmitting means responsive to application of said carrier signal for transmitting said signal to an implant in the body of a patient, gate means responsive to a control signal for gating said carrier signal to said transmitter means, means responsive to said oscillator means output for producing a sync signal indicative of the same relative point in each successive cycle of said carrier signal, and modulation means responsive to said sync signal for producing a first condition in said control signal for a first predetermined number of cycles of said carrier in response to a first condition of a data signal and for producing a second condition of said control signal for a second predetermined number of cycles of carrier signal in response to a second condition of a data signal.
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18. A two-way telemetry system for a biomedical implant, comprising
an external communications module having oscillator means for producing a continuous wave carrier signal at a constant frequency, transmitter coil means, gate means responsive to the output of the said oscillator means for producing a sync signal indicative of approximately the same point in successive cycles of carrier signal, and modulator means responsive to said sync signal for producing said control signal in one condition to said gate means for a predetermined number of cycles of carrier in response to a data input in one condition and for producing said control signal in a separate condition for a second predetermined number of cycles of carrier signal in response to a data input of a second condition whereby pulsewidth, cycle synchronized modulated bursts of carrier signals are transmitted, said external communications module further including pickup coil means, and means responsive to the output of said pickup coil means for producing an output indicative of relative phase shift of the output of said pickup coil means, and decoding means for recovering data from the output of said first detector means, and an implantable enclosure, a communications module mounted within said enclosure, including a telemetry coil tuned to said carrier frequency, a low impedance shunt circuit connected across said tuned coil including semiconductor means for modulating the impedance of said shunt circuit in accordance with a digital information signal to alter the phase and amplitude of a signal reradiated by said tuned coil in the presence of said carrier signal, second detector means coupled to said telemetry coil for producing a signal indicative of approximately the same point in each cycle of said carrier signal, missing pulse detector means responsive to the output of said second detector means for recovering transmitted data modulating said carrier signal, data timing means for producing said information signal to said shunt circuit, responsive to the output of said second detector means, in one condition for a first predetermined number of cycles of said carrier in accordance with data in one condition and for producing the information signal in a second condition for a second predetermined number of cycles of said carrier signal when the data is in a second condition.
Specification