Source management for a power transformation system

What is claimed is: 1. A battery management system for a power transformation system, the battery management system comprising: a battery having a first terminal connected to a first switch; a super capacitor having a first terminal connected to the first switch; a buck converter having a first terminal connected to a second switch; and a power stealing device connected to a third switch; and wherein: the second and third switches are connected to the first terminal of the super capacitor; a second terminal of the super capacitor is connected to a fourth switch and to a fifth switch; a second terminal of the battery is connected to a sixth switch; a second terminal of the buck converter is connected to the fifth switch, the sixth switch, and a first voltage line; a third terminal of the buck converter is connected to a seventh switch; the seventh switch is connected to the fourth switch, and a second voltage line; and the first, second, third, fourth, fifth, sixth and seventh switches are controlled by a processor. 2. The battery management system of claim 1 , wherein the battery management system is configured to operate in one or more modes of operation. 3. The battery management system of claim 1 , wherein the battery management system is configured to operate in a plurality of modes, the plurality of modes comprising: a first mode indicating that circuitry of the power transformation system is driven by the battery; a second mode indicating that the super capacitor is being charged by the battery; a third mode indicating that the second voltage line is being powered by the battery and the super capacitor is either being charged by the battery or not being charged by the battery; a fourth mode indicating that the circuitry of the power transformation system is driven by the buck converter, which is connected to a power line; a fifth mode indicating that the battery is available for charging the super capacitor and the circuitry the circuitry of the power transformation system is driven by the buck converter; and a sixth mode indicating that the first voltage line and the super capacitor are driven by the buck converter. 4. The battery management system of claim 1 , wherein the battery management system is configured to determine a battery level of the battery. 5. The battery management system of claim 4 , wherein the battery management system is configured to determine the battery level based on one or more of battery usage, battery history data, a battery level calculated from battery usage, a battery presence test, a long term expiration date of battery, battery presence test results, or battery counter information. 6. The battery management system of claim 5 , wherein a battery state based on a determination of battery level is indicated by a label selected from a group comprising good, low, very low, and critical. 7. The battery management system of claim 1 , wherein the battery management system is configured to attain a presence and condition of the battery. 8. The battery management system of claim 7 , wherein the battery management system is configured to monitor the battery for an unexpected voltage shift, read an analog value of the voltage, and the voltage, based on the value, as a load voltage or a no load voltage. 9. The battery management system of claim 8 , wherein the battery management system is configured to: obtain power stealing battery read modes from the power stealing device; and provide one or of a battery installed status, a battery no load voltage, a battery under load voltage, or and load conditions. 10. The battery management system of claim 9 , wherein the battery management system is configured to make a battery life determination from the battery under load voltage and periodical voltage measurements of the battery under load conditions. 11. The battery management system of claim 9 , wherein the battery management system is configured to make a battery life determination based on one or of a battery installed status, a battery no load voltage, a battery under load voltage, load conditions, or integration of battery current draw. 12. The battery management system of claim 10 , wherein the battery management system is configured to make: generate user interface alerts based on a battery condition status from the battery life determination; and the power stealing device is provided a battery installed status and a battery condition status. 13. A method of source management for a power transformation system, the method comprising: connecting a battery to a super capacitor via a first switch, a buck converter to the super capacitor via a second switch, and a power stealing circuit connected to the super capacitor via a third switch; and connecting a processor to the first, second and third switches; and wherein: the super capacitor is connected to a first voltage line via a fourth switch and a second voltage line via a fifth switch; the battery is connected to the first voltage line via a sixth switch; the buck converter is connected to the second voltage line via a seventh switch and to the first voltage line; the processor is connected to the fourth, fifth, sixth and seventh switches; and the processor comprises one or more algorithms to manage the battery in terms of status and output. 14. The method of claim 13 , wherein one or more modes of operation are effected by the battery management module via the one or more algorithms. 15. The method of claim 14 , wherein the one or more modes of operation at one or more times are selected from a group comprising the battery driving circuitry of the power transformation system, the super capacitor being charged by the battery, the second line voltage being powered by the battery and the super capacitor being charged by the battery, the buck converter driving the circuitry of the power transformation system, the battery being available for charging the super capacitor and the circuitry of the power transformation system being driven by the buck converter, and the buck converter driving the first voltage line and being available for charging the super capacitor. 16. The mechanism of claim 13 , a determination of the battery level is based on information selected from a group comprising battery usage, battery history data, battery level calculated from battery usage, battery presence test, long term expiration date of battery, battery presence test results, and battery counter information. 17. A battery control system, the system comprising: a super capacitor having an input connected to a charge line and having an output connected to a first voltage line and connected to a second voltage line; a battery having a first output connected to the charge line, and having a second output connected to the first voltage line; a power transformation circuit having an output connected to the charge line; a buck converter having a first output connected to the charge line, a second output connected to the first voltage line, and a third output connected to the second voltage line; and a processor connected to the battery, the power transformation circuit, and the buck converter, wherein to attain a presence and condition of the battery, the processor is configured to: monitor the battery for an unexpected voltage shift; read a value for a voltage at the battery, and categorize the voltage, based on the value, as a load voltage or a no load voltage. 18. The system of claim 17 , wherein the buck converter is configured to provide power derived from an electric AC power line.