System and method for monitoring and balancing voltage of individual battery cells within a battery pack

The invention claimed is: 1. A system for controlling monitoring and voltage balancing of individual battery cells within a battery pack supplying power to a vehicle, comprising: in a first configuration, a circuit board comprising a plurality of battery cell monitor circuits and voltage balance circuits, said plurality of battery cell monitor circuits and voltage balance circuits populated to monitor N actual total number of battery cells, where N is a number, the circuit board electrically coupled to a plurality of battery cells external to the circuit board; in a second configuration, the circuit board comprising the plurality of battery cell monitor circuits and voltage balance circuits populated to monitor less than N actual total number of battery cells, circuits included in the plurality of battery cell monitor circuits and voltage balance circuits not monitoring battery cells not being populated; and a controller including executable instructions stored in non-transitory memory to monitor and balance a first actual total number of battery circuits responsive to a first voltage across a voltage divider network and to monitor and balance a second actual total number of battery circuits responsive to a second voltage across the voltage divider network. 2. The system of claim 1 , wherein said plurality of battery cell monitor circuits includes a group of circuits having a first topology and a group of circuits having a second topology, said first topology different from said second topology, and further comprising: a first and a second resistor included with the circuit board, said first and second resistors connected in series between a first reference and a second reference, said first resistor and said second resistor sized to produce a unique voltage representing an actual total number of populated monitoring circuits and voltage balancing circuits included in the circuit board. 3. The system of claim 2 , wherein said first topology is related to a first battery cell of a battery cell stack. 4. The system of claim 1 , wherein said plurality of battery cell monitor circuits and voltage balance circuits populated on the circuit board to monitor less than N actual total number of battery cells varies with a total actual number of battery cells of a battery cell stack that are monitored. 5. The system of claim 1 , wherein said plurality of battery cell monitor circuits includes a capacitor for each of said plurality of battery cells monitored, each of said capacitors coupled in parallel to one of each of said plurality of battery cells, and further comprising two bias resistors in the plurality of battery cell monitoring circuits to control current flow to a PNP transistor that controls an operating state of a field effect transistor to select a battery cell in the plurality of battery cells for sampling, a resistance value of one of the two bias resistors based on a voltage of the battery cell in the plurality of battery cells relative to ground. 6. The system of claim 1 , wherein each circuit of said plurality of voltage balance circuits includes a switch and a load resistor, said load resistor connected in parallel with a battery cell of a battery cell stack when said switch is closed. 7. A system for controlling monitoring and voltage balancing of individual battery cells within a battery pack supplying power to a vehicle, comprising: a circuit board comprising a plurality of monitoring circuits and balancing circuits, the circuit board electrically coupled to a plurality of battery cells external to the circuit board; and a first and a second resistor included with the circuit board, said first and second resistors connected in series between a first reference and a second reference, said first resistor and said second resistor sized to produce a unique voltage representing an actual total number of populated monitoring circuits and voltage balancing circuits included in the circuit board. 8. The system of claim 7 , wherein said circuit board further includes a connector uniquely keyed to said number of populated circuits, and further comprising a controller including executable instructions stored in non-transitory memory to adjust an actual total number of monitoring circuits sampled based on the unique voltage. 9. The system of claim 7 , wherein the plurality of voltage balancing circuits include a plurality of load resistors, and further comprising two bias resistors in the plurality of monitoring circuits to control current flow to a PNP transistor that controls an operating state of a field effect transistor to select a battery cell in the plurality of battery cells external to the circuit board for sampling, a resistance value of one of the two bias resistors based on a voltage of the battery cell in the plurality of battery cells external to the circuit board relative to ground. 10. The system of claim 7 , wherein said actual total number of populated monitoring circuits and voltage balancing circuits varies with an actual total number of battery cells of a battery cell stack that are monitored. 11. The system of claim 10 , further comprising a power supply coupled to battery cells included in said actual total number of battery cells of the battery cell stack that are monitored and draining current from the plurality of battery cells within the battery pack. 12. The system of claim 7 , wherein each circuit of said plurality of monitoring circuits and balancing circuits includes a switch and a load resistor, said load resistor connected in parallel with a battery cell of a battery cell stack when said switch is closed. 13. The system of claim 7 , further comprising a microcontroller coupled to said plurality of monitoring circuits and balancing circuits and zero ohm resistors and jumpers connecting depopulated circuits to populated circuits. 14. A method for monitoring and voltage balancing a battery cell stack, said battery cell stack comprising a plurality of battery cells, an actual total number of said battery cells varying between different battery cell stacks, the method comprising: populating an actual total number of monitoring and voltage balancing circuits on a circuit board up to N monitoring and voltage balancing circuits, where N is a maximum number of battery cells arranged in series, said actual total number of monitoring and voltage balancing circuits varying between a first number of circuits and a second number of circuits, said circuit board electrically coupled to said plurality of battery cells external to said circuit board, and not populating at least one monitoring and voltage balancing circuit from said circuit board when less than N battery cells are monitored; populating a resistor network on said circuit board with resistors based on said actual total number of populated monitoring and voltage balancing circuits on said circuit board; and coupling a power supply in parallel with said plurality of battery cells, the power supply discharging the plurality of battery cells. 15. The method of claim 14 , wherein said power supply drains a portion of charge from at least one battery cell of said plurality of battery cells and is controlled by a microcontroller, and further comprising adjusting an actual total number of monitoring circuits sampled based on a voltage across a voltage divider network. 16. The method of claim 14 , wherein said power supply is a linear pass regulated power supply. 17. The method of claim 14 , wherein said circuit board is coupled to said battery cell stack via a connector uniquely keyed to correspond with said populate