Enhanced battery backup unit battery management system

What is claimed is: 1. A battery management system, comprising: a first set of back-to-back transistors configured to selectively discharge battery cells of a battery pack, the first set of back-to-back transistors comprising a first MOSFET and a second MOSFET; a first high-side driver configured to control an operation of the first set of back-to-back transistors, wherein the first MOSFET is connected to the first high-side driver via a first resistor and the second MOSFET is connected to the first high-side driver via a second resistor; a second set of back-to-back transistors comprising a third MOSFET and a fourth MOSFET; a second high-side driver configured to control an operation of the second set of back-to-back transistors, wherein the third MOSFET is connected to the second high-side driver via a third resistor and the fourth MOSFET is connected to the second high-side driver via a fourth resistor; a first auxiliary power source connected between the second MOSFET of the first set of back-to-back transistors and the third MOSFET of the second set of back-to-back transistors; a multiphase converter having a first side and a second side, wherein the first side is connected with the fourth MOSFET of the second set of back-to-back transistors; a second auxiliary power source connected to the second side of the multiphase converter; an analog front end (AFE) circuit configured to monitor a voltage of each cell within the battery pack; and a micro controller unit (MCU) configured to control and monitor the AFE circuit, provide over-voltage protection to the first and second sets of back-to-back transistors, and signal the first and second high-side drivers to place the first and second sets of back-to-back transistors in a conducting state when power from the first auxiliary power source is available and power from the second auxiliary power source is unavailable, wherein the MCU is coupled to the first and second high-side drivers. 2. The system of claim 1 , wherein the multiphase converter is configured to convert a voltage from the battery pack. 3. The system of claim 2 , further comprising an over-voltage protection circuit connected with the battery pack and configured to monitor voltages of the battery cells of the battery pack. 4. The system of claim 2 , further comprising a hot-swap circuit connected with the multiphase converter. 5. The system of claim 2 , further comprising two or more multiphase converters connected in parallel. 6. The system of claim 1 , wherein the first auxiliary power source provides power to the system during discharge of the battery pack, and the second auxiliary power source provides power to the system during a standby mode. 7. The system of claim 1 , further comprising a fuel gauge connected with the battery pack and a sensing resistor and configured to measure a current of the battery pack. 8. An electronic rack, comprising: a stack of server chassis, each server chassis including one or more servers; a power supply coupled to the server chassis to provide power to the servers; a battery backup unit (BBU) having a plurality of battery cell packages and each battery cell package containing one or more battery cells, wherein the BBU is configured to provide power to the servers when the power supply is unavailable; and a battery management system (BMS) connected between the power supply or the servers, the BMS comprising: a first set of back-to-back transistors configured to selectively discharge the plurality of battery cells of the BBU, the first set of back-to-back transistors comprising a first MOSFET and a second MOSFET; a first high-side driver configured to control an operation of the first set of back-to-back transistors, wherein the first MOSFET is connected to the first high-side driver via a first resistor and the second MOSFET is connected to the first high-side driver via a second resistor; a second set of back-to-back transistors comprising a third MOSFET and a fourth MOSFET; a second high-side driver configured to control an operation of the second set of back-to-back transistors, wherein the third MOSFET is connected to the second high-side driver via a third resistor and the fourth MOSFET is connected to the second high-side driver via a fourth resistor; a first auxiliary power source connected between the second MOSFET of the first set of back-to-back transistors and the third MOSFET of the second set of back-to-back transistors; a multiphase converter having a first side and a second side, wherein the first side is connected with the fourth MOSFET of the second set of back-to-back transistors; a second auxiliary power source connected to the second side of the multiphase converter; an analog front end (AFE) circuit configured to monitor a voltage of each cell within the BBU; and a micro controller unit (MCU) configured to control and monitor the AFE circuit, provide over-voltage protection to the first and second sets of back-to-back transistors, and signal the first and second high-side drivers to place the first and second sets of back-to-back transistors in a conducting state when power from the first auxiliary power source is available and power from the second auxiliary power source is unavailable, wherein the MCU is coupled to the first and second high-side drivers. 9. The electronic rack of claim 8 , wherein the BMS further comprises a multiphase converter connected with the second set of back-to-back transistors and configured to convert voltage from the BBU. 10. The electronic rack of claim 9 , wherein the BMS further comprises an over-voltage protection circuit connected with the BBU and configured to monitor the battery cells of the BBU. 11. The electronic rack of claim 9 , wherein the BMS further comprises a hot-swap circuit connected with the multiphase converter. 12. The electronic rack of claim 9 , wherein the BMS further comprises two or more multiphase converters connected in parallel. 13. The electronic rack of claim 8 , wherein the first auxiliary power source provides power to the BMS during discharge of the BBU, and the second auxiliary power source provides power to the system during standby mode. 14. The electronic rack of claim 8 , wherein the BMS further comprises a fuel gauge connected with the BBU and a sensing resistor and configured to measure a current of the BBU. 15. A method of managing a battery pack, the method comprising: monitoring a voltage of each cell within a battery pack using an analog front end (AFE) circuit within a battery management system (BMS); controlling first and second sets of back-to-back transistors via first and second high-side drivers within the BMS to selectively discharge cells within the battery pack, the first set of back-to-back transistors comprising a first MOSFET and a second MOSFET and the second set of back-to-back transistors comprising a third MOSFET and a fourth MOSFET with the fourth MOSFET connected to a first side of a multiphase converter, the first MOSFET connected to the first high-side driver via a first resistor, the second MOSFET connected to the first high-side driver via a second resistor, the third MOSFET connected to the second high-side driver via a third resistor, and the fourth MOSFET connected to the second high-side driver via a fourth resistor; and controlling and monitoring the AFE circuit using a micro controller unit (MCU) within the BMS, wherein the MCU is coupled to the first and second high-side driver and the MCU provides over-voltage protection to the first and second sets of back-to-back transistors signaling the first and second high-side dri