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Systems and methods for management of a backup power system are described herein. At least one illustrative embodiment includes a backup power system configured to couple to a power source including a plurality of batteries, each comprising one or more cells, used to provide power if the power sourc

Systems and methods for management of a backup power system are described herein. At least one illustrative embodiment includes a backup power system configured to couple to a power source including a plurality of batteries, each comprising one or more cells, used to provide power if the power source fails, and processing logic coupled to the batteries and configured to monitor the state of each of the plurality of batteries and control the charging and discharging of each of the plurality of batteries. If the power source has not failed, the processing logic repeatedly and sequentially causes each battery to discharge while at least one of the remaining batteries remains fully charged, and monitors the power provided by the discharging battery. The processing logic determines the available energy stored in each fully charged battery based upon the power provided by the discharging battery during the time it takes to discharge.

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1. A backup power system configured to be coupled to a power source, comprising: a plurality of batteries each comprising one or more cells and used to provide power if a power source fails; andprocessing logic coupled to the plurality of batteries, configured to monitor a state of each of the plura

1. A backup power system configured to be coupled to a power source, comprising: a plurality of batteries each comprising one or more cells and used to provide power if a power source fails; andprocessing logic coupled to the plurality of batteries, configured to monitor a state of each of the plurality of batteries, and further configured to control a charging and discharging of each of the plurality of batteries;wherein, if the power source has not failed, the processing logic repeatedly and sequentially causes each of the plurality of batteries to discharge while at least one of the remaining batteries remains fully charged, and further monitors a power provided by each of the plurality of batteries while discharging;wherein the processing logic determines an available energy stored in each discharging battery when fully charged based upon a power provided by the discharging battery during a time it takes for the discharging battery to discharge; andwherein the processing logic causes a battery of the plurality of batteries not to be used to provide backup power based on the battery's available energy being determined to be below a minimum operating threshold value. 2. The backup power system of claim 1, further comprising a synthetic load, wherein the processing logic causes the discharging battery to couple to the synthetic load and to discharge through the synthetic load. 3. The backup power system of claim 1, wherein the discharge of each of the plurality of batteries is not performed if the at least one of the remaining batteries combined do not store enough combined energy to equal or exceed a minimum energy reserve threshold value. 4. The backup power system of claim 1, wherein the processing logic generates a signal when the battery is made unavailable, the signal indicative of which of the plurality of batteries has an available energy level below the minimum operating threshold value. 5. The backup power system of claim 1, wherein at least one battery is coupled to a power-providing node of the system during normal operation of the backup power system. 6. The backup power system of claim 1, wherein the processing logic causes the plurality of batteries to be uncoupled from a power-providing node if the processing logic detects a voltage at the power-providing node above a maximum operating voltage, or below a minimum operating voltage. 7. The backup power system of claim 1, wherein a first battery of the plurality of batteries is coupled to a power-providing node, and a second battery of the plurality of batteries is not coupled to the power-providing node; andwherein if the processing logic detects a failure of the power source, and further detects that the difference between the voltage of the first battery and the second battery is less than a minimum voltage difference threshold value, the processing logic causes the second battery to be coupled to the power-providing node. 8. A method of maintaining a backup power system configured to be coupled to a power source, comprising: storing power in a plurality of batteries each battery comprising one or more cells and used to provide power if a power source fails;monitoring the state of each of the plurality of batteries;repeatedly and sequentially discharging each battery of the plurality of batteries while at least one of the remaining batteries of the plurality remains fully charged, if a primary power source, which provides power to a device external and coupled to each battery, has not failed;monitoring the power delivered by each discharging battery over time;determining the energy stored within each discharging battery based upon the power delivered over a discharge time of each discharging battery;causing a battery of the plurality of batteries to not be used to provide backup power and for recharging based on the battery's available energy being determined to be below a minimum operating threshold; andcharging each battery of the plurality of batteries after discharging. 9. The method of claim 8, wherein repeatedly discharging each battery comprises coupling each battery to a synthetic load. 10. The method of claim 8, further comprising repeatedly discharging each battery by providing power to a device external and coupled to each battery, if the primary power source previously providing power to the device has failed. 11. The method of claim 8, wherein repeatedly discharging each battery is not performed unless the total energy stored in each of the remaining plurality of batteries combined equals or exceeds a minimum reserve threshold value. 12. The method of claim 8, further comprising identifying a battery of the plurality of batteries as failed if the energy stored within the battery is below a minimum operating threshold value. 13. The method of claim 12, further comprising generating a signal indicating which of the plurality of batteries has failed. 14. The method of claim 8, further comprising uncoupling the plurality of batteries from an external device if the voltage measured at a power input node of the external device is above a maximum operating voltage, or below a minimum operating voltage. 15. The method of claim 8, further comprising: monitoring a first voltage of a first battery of the plurality of batteries, the first battery coupled to, and discharging through, a device external to the plurality of batteries;monitoring a second voltage of a second battery of the plurality of batteries, the second battery not coupled to the device; andcoupling the second battery to the device when the difference between the first voltage and the second voltage is below a minimum voltage difference threshold value. 16. A non-transitory computer-readable storage medium for maintaining a backup power system configured to be coupled to a power source, comprising software that causes a processor to: cause power to be stored in a plurality of batteries;monitor the state of each of the plurality of batteries;repeatedly and sequentially cause the discharge of each of the plurality of batteries while at least one of the remaining batteries of the plurality remains fully charged, if a primary power source, which provides power to a device external and coupled to each battery, has not failed;monitor the power delivered by each discharging battery over time;determine the energy stored within each discharging battery based upon the power delivered over a discharge time of each discharging battery;cause a battery of the plurality of batteries to not be used to provide backup power and for recharging based on the battery's available energy being determined to be below a minimum operating threshold; andcause each battery of the plurality of batteries to be charged after discharge. 17. The non-transitory computer-readable storage medium of claim 16, wherein repeatedly causing the discharge of each battery comprises causing each battery to be coupled to a synthetic load. 18. The non-transitory computer-readable storage medium of claim 16, the software further causing the processor to repeatedly cause the discharge of each battery by causing each battery to provide power to a device external and coupled to each battery if the primary power source previously providing power to the device has failed. 19. The non-transitory computer-readable storage medium of claim 16, wherein the software does not cause the processor to repeatedly cause the discharge of each battery unless the total energy stored in each of the remaining plurality of batteries combined equals or exceeds a minimum reserve threshold value. 20. The non-transitory computer-readable storage medium of claim 16, the software further causing the processor to identify a battery of the plurality of batteries as failed if the energy stored within the battery is below a minimum operating threshold value. 21. The non-transitory computer-readable storage medium of claim 20, the software further causing the processor to generate a signal indicating which of the plurality of batteries has failed. 22. The non-transitory computer-readable storage medium of claim 16, the software further causing the processor to uncouple the plurality of batteries from an external device if the voltage measured at a power input node of the external device is above a maximum operating voltage, or below a minimum operating voltage. 23. The non-transitory computer-readable storage medium of claim 16, the software further causing the processor to: monitor a first voltage of a first battery of the plurality of batteries, the first battery coupled to, and discharging through, a device external to the plurality of batteries;monitor a second voltage of a second battery of the plurality of batteries, the second battery not coupled to the device; andcouple the second battery to the device when the difference between the first voltage and the second voltage is below a minimum voltage difference threshold value.