Ground fault detection of UPS battery

The invention claimed is: 1. A method for detecting a ground fault in a battery of an uninterrupted power supply, the battery comprises at least one string with multiple battery cells, the method comprising the steps of: defining, by a battery management system, multiple individual battery blocks of battery cells along the at least one string, performing, by the battery management system, a reference impedance measurement of the multiple individual battery blocks at a first point of time, performing, by the battery management system, a verification impedance measurement for the multiple individual battery blocks at a second point of time, evaluating, by the battery management system, a change of measured impedance between the reference impedance and the verification impedance for the multiple individual battery blocks of the at least one string, and identifying, by the battery management system, a ground fault based on a correlated change of measured impedance of the multiple individual battery blocks along the at least one string, wherein the step of identifying a ground fault based on a correlated change of measured impedance of the individual battery blocks along the at least one string comprises a step of localizing a position of the ground fault by identifying a sequence of individual battery blocks on one side of the ground fault with a correlated change of measured impedance compared to another sequence of individual battery blocks on the other side of the ground fault along the at least one string. 2. The method according to claim 1 , wherein the step of defining multiple individual battery blocks of battery cells along the at least one string comprises defining each of the multiple individual battery blocks comprising few individual battery cells. 3. The method according to claim 2 , wherein the steps of performing a reference impedance measurement and performing a verification impedance measurement for the multiple individual battery blocks each comprise: generating, by the battery management system, at least one current pulse through the battery, measuring, by the battery management system, a voltage across each of the multiple individual battery blocks as response to the at least one current pulse, measuring, by the battery management system, a current across the multiple individual battery blocks as response to the at least one current pulse, and determining, by the battery management system, the impedance of each individual battery block based on the voltage and the current measured across the individual battery block as response to the at least one current pulse. 4. The method according to claim 3 , wherein the step of generating at least one current pulse through the battery comprises generating at least one charge pulse and/or at least one discharge pulse. 5. The method according to claim 1 , wherein the steps of performing a reference impedance measurement and performing a verification impedance measurement for the multiple individual battery blocks each comprise: generating, by the battery management system, at least one current pulse through the battery, measuring, by the battery management system, a voltage across each of the multiple individual battery blocks as response to the at least one current pulse, measuring, by the battery management system, a current across the multiple individual battery blocks as response to the at least one current pulse, and determining, by the battery management system, the impedance of each individual battery block based on the voltage and the current measured across the individual battery block as response to the at least one current pulse. 6. The method according to claim 5 , wherein the step of generating at least one current pulse through the battery comprises generating at least one charge pulse and/or at least one discharge pulse. 7. The method according to claim 6 , wherein the step of generating at least one current pulse through the battery comprises generating a current pulse train. 8. The method according to claim 7 , wherein the method further comprises verifying a validity of the reference impedance measurement based on an elapsed period of time between the reference impedance measurement and the verification impedance measurement, and performing a further reference impedance measurement when the elapsed period of time exceeds a given time limit. 9. The method according to claim 5 , wherein the step of generating at least one current pulse through the battery comprises generating a current pulse train. 10. The method according to claim 6 , wherein the method further comprises verifying a validity of the reference impedance measurement based on an elapsed period of time between the reference impedance measurement and the verification impedance measurement, and performing a further reference impedance measurement when the elapsed period of time exceeds a given time limit. 11. The method according to claim 1 , wherein the method further comprises verifying a validity of the reference impedance measurement based on an elapsed period of time between the reference impedance measurement and the verification impedance measurement, and performing a further reference impedance measurement when the elapsed period of time exceeds a given time limit. 12. The method according to claim 1 , wherein the step of identifying a sequence of individual battery blocks with a correlated change of measured impedance compared to another sequence of individual battery blocks along the at least one string comprises determining a change of measured impedance individually for each individual battery block. 13. The method according to claim 12 , wherein the step of identifying a sequence of individual battery blocks with a correlated change of measured impedance compared to another sequence of individual battery blocks along the at least one string comprises performing a change detection algorithm or a signal segmentation algorithm. 14. The method according to claim 1 , wherein the step of identifying a sequence of individual battery blocks with a correlated change of measured impedance compared to another sequence of individual battery blocks along the at least one string comprises performing a change detection algorithm or a signal segmentation algorithm. 15. A battery management system for managing a battery of an uninterrupted power supply, the battery comprising at least one string with multiple battery cells, the battery management system is operable to: define multiple individual battery blocks of battery cells along the at least one string; perform a reference impedance measurement of the multiple individual battery blocks at a first point of time; perform a verification impedance measurement for the multiple individual battery blocks at a second point of time; evaluate a change of measured impedance between the reference impedance and the verification impedance for the multiple individual battery blocks of the at least one string; and identify a ground fault based on a correlated change of measured impedance of the multiple individual battery blocks along the at least one string; wherein the step of identifying a ground fault based on a correlated change of measured impedance of the individual battery blocks along the at least one string comprises a step of localizing a position of the ground fault by identifying a sequence of individual battery blocks on one side of the ground fault with a correlated change of measured impedance compared to another sequence of individual battery blocks on the other side of the ground fault along the at least one string.