초록 ▼

A system is described which has a battery, a device which is powered by the battery in an episodic manner, and a charge storage capacitor. The system has attached to the charge storage capacitor a device or devices capable of: reading the rate of charge storage; or measuring both time and charge sto

A system is described which has a battery, a device which is powered by the battery in an episodic manner, and a charge storage capacitor. The system has attached to the charge storage capacitor a device or devices capable of: reading the rate of charge storage; or measuring both time and charge stored or added to the charge storage capacitor so that a rate of charge storage may be calculated. The estimated replacement time for the battery, particularly for a lithium battery in a pacing device, is easily estimated. Also described herein is a process for estimating a level of energy depletion in the system. The process comprises: finding a relatively quiescent period in powering of the device in the episodic manner; determining a rate of charging in the storage capacitor during the quiescent period; and correlating the rate of charging in the storage capacitor to a value of internal impedance in the battery through a comparison with known relationships for the battery and rate of charging to determine a value for the internal impedance of the battery.

대표청구항 ▼

What is claimed: 1. A pacemaker, including: a battery power terminal for a pacemaker battery; a capacitor electrically connected to the battery power terminal; pacemaker control circuitry electrically connected to the battery power terminal and the capacitor for controlling current flow from the ba

What is claimed: 1. A pacemaker, including: a battery power terminal for a pacemaker battery; a capacitor electrically connected to the battery power terminal; pacemaker control circuitry electrically connected to the battery power terminal and the capacitor for controlling current flow from the battery power terminal to the capacitor to charge the capacitor and to discharge the capacitor to a discharge voltage level (Vd) before beginning a time charge measurement; and charge time measurement (CTM) control circuitry electrically connected to the pacemaker control circuitry and adapted to: access a predetermined set of charge time measurement set-up parameters and a predetermined elective replacement time (ERT) charge time limit associated with an AC impedance target for the battery; determine a rate of charge storage in the capacitor using the predetermined set of charge time measurement set-up parameters; and declare an ERT using the determined rate of charge storage in the capacitor and the ERT charge time limit, wherein the predetermined set of charge time measurement set-up parameters to be accessed by the CTM control circuitry include: a final capacitor voltage (VF) to end the charge time measurement for determining the rate of charge storage in the capacitor; and an initial capacitor reference voltage (VI) to begin the charge time measurement for determining the rate of charge storage in the capacitor, VI being greater than Vd. 2. The pacemaker of claim 1, wherein the pacemaker control circuitry includes comparison circuitry for comparing a battery terminal voltage (Vbatt) to a brownout voltage limit (Vstop), and for comparing a capacitor voltage (Vcs) to one of the predetermined set of charge time measurement set-up parameters. 3. The pacemaker of claim 2, wherein the pacemaker control circuitry further includes a switched capacitor power supply operably connected to the battery power terminal and the capacitor for charging the capacitor, wherein an output of the comparison circuitry is electrically connected to the switched capacitor power supply to control current flow from the battery power terminal to the capacitor. 4. The pacemaker of claim 1, wherein the pacemaker control circuitry controls current flow to the capacitor to increase a capacitor voltage (VCS) approximately linearly from VI to VF during the time measurement for determining the rate of charge storage in the capacitor. 5. The pacemaker of claim 1, wherein: the CTM control circuitry includes a multiplexer for selecting one of VF and VI to be compared to a capacitor voltage level (Vcs) within the pacemaker control circuitry; and the CTM control circuitry is adapted to select VI to be compared to Vsc to begin a time charge measurement and VF to be compared to Vcs to end the time charge measurement. 6. The pacemaker of claim 1, wherein the CTM control circuitry includes a time charge counter for measuring a time in which a relatively constant current charges the capacitor from VI to VF. 7. The pacemaker of claim 1, wherein the pacemaker control circuitry includes a sensing and pacing control block adapted for selecting VI. 8. The pacemaker of claim 1, wherein the CTM control circuitry includes a multiplexer for selecting one of the VF, VI and Vd to be compared to a capacitor voltage level (Vcs). 9. The pacemaker of claim 8, further comprising: a capacitor discharge switch; a bypass capacitor connected across the battery power terminal; and means to provide a brown out voltage limit; wherein the CTM control circuitry is adapted to compare: Vd to Vcs to limit the discharge of the capacitor and open the capacitor discharge switch; VI to Vcs to begin a time charge measurement after the bypass capacitor (Cb) is discharged and a battery terminal voltage (Vbatt) is driven to the brownout voltage (Vstop) limit; and VF to Vcs to end the time charge measurement. 10. The pacemaker of claim 1, wherein the VF is programmable by a physician. 11. The pacemaker of claim 1, wherein the CTM control circuitry includes: a memory; and means for loading the memory with a pacing voltage amplitude value to function as the charged voltage reference (VF), an initial value to function as the initial voltage reference (VI), and a discharge value to function as the discharged voltage reference (Vd). 12. The pacemaker of claim 1, wherein the pacemaker battery is a lithium battery. 13. A system, comprising: a battery power terminal for a battery; a capacitor electrically connected to the battery power terminal; means to control current flow from the battery power terminal to charge the capacitor; means to access a predetermined set of charge time measurement set-up parameters and a predetermined elective replacement time (ERT) charge time limit associated with an AC impedance target for the battery, the predetermined set of charge time measurement set-up parameters including: a charged capacitor voltage reference (VF) to end a charge time measurement for determining the rate of charge storage in the capacitor; an initial capacitor voltage reference (VI) to begin the charge time measurement for determining the rate of charge storage in the capacitor; and a discharge voltage reference (Vd) to which the capacitor is discharged prior to beginning the time measurement for determining the rate of charge storage in the capacitor, Vd being less than VI; means to determine a rate of charge storage in the capacitor using the predetermined set of charge time measurement set-up parameters; means to compare the determined rate of charge storage in the capacitor to the predetermined ERT charge time limit for the predetermined set of charge time measurement set-up parameters; and means to declare an ERT based on a number of comparisons between the determined rate of charge storage in the capacitor and the ERT charge time limit. 14. The system of claim 13, wherein further comprising: means to calculate an AC impedance of the battery using the determined rate of charge storage and the predetermined set of charge time measurement set-up parameters; and means to determine the ERT charge time limit using the AC impedance of the battery. 15. The system of claim 13, further comprising: a table containing relationships between a number of AC impedances for the battery and a number of rates of charge storage; means to perform a table look-up using the table and the determined rate of charge storage to determine the AC impedance of the battery; and means to determine the ERT charge time limit using the AC impedances. 16. The system of claim 13, further comprising means to display charge remaining in the battery. 17. The system of claim 16, wherein the programmer circuitry includes means to graphically display the charge remaining in the battery. 18. The system of claim 13, further comprising means to estimate a time until the ERT is declared. 19. The system of claim 13, wherein the means to determine a rate of charge storage in the capacitor includes: means to compare a voltage across the storage capacitor (Vcs) to the discharge voltage reference while discharging the storage capacitor to the discharge voltage reference; means to compare Vcs to the initial voltage reference while charging the storage capacitor, and to initiate the measuring of the charge time for the storage capacitor when Vcs reaches the initial voltage reference; and means to compare Vcs to the charged voltage reference while charging the storage capacitor to the charged voltage reference, and ending the measuring of the charge time for the storage capacitor when Vcs reaches the charged voltage reference. 20. The system of claim 13, wherein the battery is a lithium battery.