Fault tolerant voltage measurement method

What is claimed is: 1. A method for detecting a fault condition in a string of battery cells arranged in series, comprising: grouping N battery cells into L groups of cells, each group of cells is comprised of a combination of two or more battery cells, each cell is associated with at least two of the L groups of cells, and each combination of battery cells is comprised of battery cells which differ from the other combination of battery cells; measuring voltage across each group in the L groups of battery cells using M voltage sensors, such that each voltage sensor of the M voltage sensors measures voltage across a different group of the L groups of battery cells; representing cell voltages for each cell in the N battery cells as a matrix, C; representing voltage measurements for each group in the L groups of battery cell as a matrix, V; representing a mapping between each voltage measurement and the battery cells whose sum corresponds to the voltage measurement in a matrix, A; determining current cell voltages using matrix multiplication, wherein the relationship is expressed as V=AC; and identifying a fault with one of the M voltage sensors when voltage measure of at least one battery cell in the L groups of battery cells increase while voltage measure of at least one battery cell in the L groups of battery cells decreases. 2. The method of claim 1 wherein determining a fault condition further comprises defining one or more relationships between cell voltage for each cell in the N battery cells and the voltage measurements for each group in the L groups of battery cells; and determining current cell voltages for each battery cell using the relationships and the voltage measurements for each group in the L groups of battery cells. 3. The method of claim 1 wherein each of the L groups of cells is comprised on K battery cells, where N and K are relative prime numbers. 4. The method of claim 1 wherein determining a fault condition further comprises identifying a fault with one of the N battery cells from two or more of the voltage measurements. 5. The method of claim 4 where a fault with one of the N battery cells is identified by solving C fault =C−C normal =A −1 V−C normal where is cell voltage values in normal working condition and C fault is the impact of the fault conditions. 6. The method of claim 1 wherein a fault with one of the M voltage sensors is identified by V fault =V−V normal =V−AC normal where V normal is a normal sensor reading and V fault is the impact of the fault conditions. 7. A method for detecting a fault condition in a string of battery cells arranged in series, comprising: grouping N battery cells into L groups of cells, each group of cells is comprised of a combination of two or more battery cells and each combination of battery cells is comprised of battery cells which differ from the other combination of battery cells; measuring voltage across each group in the L groups of battery cells using M voltage sensors, such that each voltage sensor of the M voltage sensors measures voltage across a different group of the L groups of battery cells; and representing cell voltages for each cell in the N battery cells as a matrix, C; representing voltage measurements for each group in the L groups of battery cell as a matrix, V; representing a mapping between each voltage measurement and the battery cells whose sum corresponds to the voltage measurement in a matrix, A; and determining current cell voltages using matrix multiplication, wherein the relationship is expressed as V=AC. 8. The method of claim 7 further comprises determining a fault with one of the N battery cells is identified by solving C fault =C−C normal =A −1 V−C normal where is cell voltage values in normal working condition and C fault is the impact of the fault conditions. 9. The method of claim 7 further comprises determining a fault with one of the M voltage sensors is identified by V fault =V−V normal =V−AC normal where V normal is a sensor reading and V fault is the impact of the fault conditions. 10. A battery management system, comprising: N battery cells connected in series, where the N battery cells are grouped into L groups of cells, each group of cells having a combination of two or more battery cells, each cell is associated with at least two of the L groups of cells, and each combination of battery cells is comprised of battery cells which differ from the other combinations of battery cells; M voltage sensors electrically coupled across the N battery cells, where each voltage sensor of the M voltage sensors is configured to measure voltage across a different group of the L groups of battery cells; and a controller electrically coupled to each of the M voltage sensors and operates, in response to voltage measures from the M voltage sensors, to determine a fault condition using the voltage measurements from each group in the L groups of battery cells, wherein the controller determines cell voltages using a relationship expressed as V=AC; where cell voltages for each cell in the N battery cells is represented as a matrix, C; voltage measurements for each group in the L groups of battery cell are presented as a matrix, V; and a mapping between each voltage measurement and the battery cells whose sum corresponds to the voltage measurement is represented in a matrix, A. 11. The battery management system of claim 10 wherein the controller identifies a fault with one of the N battery cells from two or more of the voltage measurements. 12. The battery management system of claim 10 wherein the controller identifies a fault with one of the M voltage sensors when voltage measure of one or more battery cells in the L groups of battery cells increase while voltage measure of another one or more battery cells in the L groups of battery cells decreases. 13. The battery management system of claim 10 wherein the controller identifies a fault with one of the N battery cells by solving C fault =C−C normal =A −1 V−C normal where is cell voltage values in normal working condition and C fault is the impact of the fault conditions. 14. The battery management system of claim 13 wherein the controller identifies a fault with one of the M voltage sensors by V fault =V−V normal =V−AC normal where V normal is a normal sensor reading and V fault is the impact of the fault conditions. 15. The battery management system of claim 10 resides in a vehicle.