Battery system and method for determining battery module voltages

The invention claimed is: 1. A battery system comprising: at least two battery modules connected in series to provide a battery voltage, each of the at least two battery modules comprising: a plurality of battery cells connected in series to provide a battery module voltage; a cell voltage sensing unit configured to measure a battery cell voltage of each battery cell of the plurality of battery cells; and a module voltage sensing unit configured to measure the battery module voltage independently of the cell voltage sensing unit; and a central controller, the central controller being operatively connected to the cell voltage sensing unit of each of the at least two battery modules via a common communication bus, the central controller being operatively connected to the module voltage sensing unit of each of the at least two battery modules via separate connections. 2. The battery system as claimed in claim 1 , the module voltage sensing units of the at least two battery modules comprising: a plurality of module measuring lines routed to the central controller, each module voltage sensing unit having a first module measuring line of the plurality of module measuring lines connected to a positive pole of the respective battery module and a second module measuring line of the plurality of module measuring lines connected to a negative pole of the respective battery module. 3. The battery system as claimed in claim 2 , each module voltage sensing unit comprising: an optocoupler having an input side connected to the plurality of module measuring lines and an output side connected to the central controller. 4. The battery system as claimed in claim 3 , the optocoupler comprising: an input resistor; a diode; and a transistor. 5. A method for determining battery module voltages in a battery system including at least two battery modules connected in series to provide a battery voltage, each of the at least two battery modules including (i) a plurality of battery cells connected in series to provide a battery module voltage, (ii) a cell voltage sensing unit configured to measure a battery cell voltage of each battery cell of the plurality of battery cells, and (iii) a module voltage sensing unit configured to measure the battery module voltage independently of the cell voltage sensing unit, the method comprising: measuring the battery cell voltages the battery cells of each plurality of battery cells with the respective cell voltage sensing units; transmitting the measured battery cell voltages via a common communication bus to a central controller, the central controller being operatively connected to the cell voltage sensing unit of each of the at least two battery modules via the common communication bus; measuring the battery module voltages of each battery module with the respective module voltage sensing units; and transmitting the measured battery module voltages to the central controller, the central controller being operatively connected to the module voltage sensing unit of each of the at least two battery modules via separate connections. 6. The method as claimed in claim 5 , further comprising: detecting a failure of at least one of the cell voltage sensing units by comparing the transmitted battery cell voltages with reference voltage values with the central controller; measuring a current delivered at present by the battery system with the central controller; determining the battery cell voltages of the battery cells from the measured current with the central controller; calculating the battery module voltages of the battery modules from the determined battery cell voltages of the battery cells with the central controller; determining a difference in the determined battery module voltages of the battery modules with the transmitted battery module voltages with the central controller; comparing an absolute value of the determined difference with a prescribed tolerance value with the central controller; and disconnecting the battery system if the absolute value of the determined difference exceeds the prescribed tolerance value with the central controller. 7. The method as claimed in claim 6 , wherein the steps of measuring the current, determining the battery cell voltages, calculating the battery module voltages, determining the difference, and comparing the absolute value of the determined difference are each continuously repeated at a rate of repetition. 8. The method as claimed in claim 7 , wherein the rate of repetition is greater than 0.1 Hz. 9. The method as claimed in claim 7 , wherein the rate of repetition is greater than 10 Hz. 10. A motor vehicle comprising: a drive system; and a battery system connected to the drive system, the battery system comprising: at least two battery modules connected in series to provide a battery voltage, each of the at least two battery modules comprising: a plurality of battery cells connected in series to provide a battery module voltage; a cell voltage sensing unit configured to measure a battery cell voltage of each battery cell of the plurality of battery cells; and a module voltage sensing unit configured to measure the battery module voltage independently of the cell voltage sensing unit; and a central controller, the central controller being operatively connected to the cell voltage sensing unit of each of the at least two battery modules via a common communication bus, the central controller being operatively connected to the module voltage sensing unit of each of the at least two battery modules via separate connections.