IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0870340
(2001-05-29)
|
발명자
/ 주소 |
|
출원인 / 주소 |
|
인용정보 |
피인용 횟수 :
22 인용 특허 :
7 |
초록
▼
A telemetry system for use in an implantable device that communicates with an external programmer, includes a coil, a timing circuit connected to the coil, and a coil driver circuit that reverts at least part of the expanded energy back to the power source. The timing circuit generates two control s
A telemetry system for use in an implantable device that communicates with an external programmer, includes a coil, a timing circuit connected to the coil, and a coil driver circuit that reverts at least part of the expanded energy back to the power source. The timing circuit generates two control signals SC1 and SC2, and is comprised of four switches S1, S2, S3, S4 that are connected across the power source and the coil, and that are selectively energized by the control signals SC1 and SC2. The control signal SC1 energizes switches S1 and S4 to close, with the switches S2 and S3 open, causing the coil to become a load across the power source and to store energy therefrom. Upon the expiration of the control signal SC1, the control signal SC2 triggers switches S2 and S3 to close with the switches S1 and S4 open, causing the coil to discharge the stored energy through the power source, charging it.
대표청구항
▼
A telemetry system for use in an implantable device that communicates with an external programmer, includes a coil, a timing circuit connected to the coil, and a coil driver circuit that reverts at least part of the expanded energy back to the power source. The timing circuit generates two control s
A telemetry system for use in an implantable device that communicates with an external programmer, includes a coil, a timing circuit connected to the coil, and a coil driver circuit that reverts at least part of the expanded energy back to the power source. The timing circuit generates two control signals SC1 and SC2, and is comprised of four switches S1, S2, S3, S4 that are connected across the power source and the coil, and that are selectively energized by the control signals SC1 and SC2. The control signal SC1 energizes switches S1 and S4 to close, with the switches S2 and S3 open, causing the coil to become a load across the power source and to store energy therefrom. Upon the expiration of the control signal SC1, the control signal SC2 triggers switches S2 and S3 to close with the switches S1 and S4 open, causing the coil to discharge the stored energy through the power source, charging it. according to claim 9, further including a device connected across the second switch that is operative to allow a current through the telemetry coil to flow in one direction. 11. The telemetry system according to claim 9, wherein the first control signal closes the first switch to cause the capacitor to become a load across the energy source and to be charged. 12. The telemetry system according to claim 11, wherein the second control signal cyclically closes the second switch to cause the capacitor to become an energy source and the telemetry coil to become a load across the capacitor, and the voltage and current in the telemetry coil and capacitor circuit to sinusoidally oscillate, discharging and then charging back the capacitor. 13. The telemetry system according to claim 1 for use with an external programmer, and wherein the programmer includes: a bandpass filter; and a synchronous demodulator that demodulates signals received from the implantable device. 14. The telemetry system according to claim 13, wherein the programmer further includes an integrator that integrates the signal demodulated by the synchronous demodulator. 15. The telemetry system according to claim 14, wherein the programmer further includes a digitizer that samples and digitizes signals integrated by the integrator. 16. The telemetry system according to claim 12, wherein the synchronous demodulator includes a switch and a phase shift circuit. 17. The telemetry system according to claim 12, wherein the programmer further includes a zero-crossing detector on the received signal that generates a controller interrupt. 18. The telemetry system according to claim 17, wherein the zero-crossing detector includes a hard limiter. 19. A telemetry system for use in an implantable stimulation device, the telemetry system comprising: a telemetry coil; an energy source that supplies energy to the telemetry coil; a switching circuit coupled between the energy source and the telemetry coil, and adapted to selectively couple the energy source to the telemetry coil in at least two configurations; and a timing circuit coupled to the switching circuit for controlling the coupling of the energy source to the telemetry coil in the at least two configurations, so that at least a portion of the energy supplied to the telemetry coil is returned to the energy source when the switching circuit assumes one of the configurations. 20. A telemetry system for use in an implantable stimulation device comprising: telemetry coil means; energy means for supplying energy to the telemetry coil means; and switch means for switchably coupling the energy means to the telemetry coil means in at least two configurations for respectively providing energy to the telemetry coil and delivering at least a portion of the energy in the telemetry coil means to the energy means. 21. The telemetry system according to claim 20, further including timing means for generating first and second control signals; wherein the switch means is comprised of four switches that are generally configured as an H-bridge across the telemetry coil means, and wherein the four switches are selectively energized by the respective first and second control signals to assume the respective configurations. 22. The telemetry system according to claim 21, wherein the first control signal cyclically closes a first pair of said switches, while a second pair of said switches remain open, causing the telemetry coil means to become a load across the energy means; and wherein the second control signal closes said second pair of switches, while the first pair of said switches remain open, causing the telemetry coil to discharge stored energy into the energy source.
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