Systems and methods for compensating current in a battery module

We claim: 1. A battery module, comprising: a battery pack comprising a plurality of cells; and a plurality of control circuits corresponding to the plurality of cells, each control circuit comprising: a control unit, operable for managing the corresponding cell, the control unit operating with a corresponding consumed current; and a compensation unit, coupled to the control unit, that is operable for generating a corresponding compensation current such that the sum of the corresponding consumed current and the corresponding compensation current is equal to a target total current. 2. The battery module of claim 1 , wherein the plurality of control circuits comprise a first control circuit and a second control circuit, the first control circuit comprising a first control unit operating with a first consumed current, the second control circuit comprising a second control unit operating with a second consumed current, and wherein the first control circuit is operable for generating a first compensation current and the second control circuit is operable for generating a second compensation current, wherein the target total current is determined by a control unit that operates with a highest consumed current among a plurality of control units in the plurality of control circuits. 3. The battery module of claim 2 , wherein if the first consumed current is greater than the second consumed current, then the second control circuit generates the second compensation current such that the sum of the second consumed current and the second compensation current is equal to the target total current. 4. The battery module of claim 2 , wherein if the second consumed current is greater than the first consumed current, then the first control circuit generates the first compensation current such that the sum of the first consumed current and the first compensation current is equal to the target total current. 5. The battery module of claim 2 , further comprising: a plurality of detection units, wherein one of the detection units is coupled between the first control circuit and the second control circuit, operable for generating a detection signal indicative of a difference between the first consumed current and the second consumed current, wherein the first control circuit and the second control circuit generate the first compensation current and the second compensation current, respectively, based on the detection signal. 6. The battery module of claim 5 , wherein each detection unit comprises two diodes connected back-to back in parallel. 7. The battery module of claim 6 , wherein each detection unit detects voltages at the two diodes to generate the detection signal. 8. The battery module of claim 1 , wherein each compensation unit comprises: a first compensation branch operable for generating a first branch current; and a second compensation branch operable for generating a second branch current, wherein the sum of the first branch current and the second branch current is equal to the corresponding compensation current. 9. The battery module of claim 8 , wherein the first compensation branch comprises a first operational amplifier and a first switch controlled by an output of the first operational amplifier, wherein the second compensation branch comprises a second operational amplifier and a second switch controlled by an output of the second operational amplifier. 10. The battery module of claim 1 , wherein if the battery module enters a balanced working state, then there is no current flowing through a plurality of paths between the plurality of cells and the plurality of control circuits. 11. A method comprising: operating a first control unit of a battery module with a first consumed current, the battery module further comprising a plurality of cells and a plurality of control circuits; operating a second control unit of the battery module with a second consumed current; detecting a difference between the first consumed current and the second consumed current based on a detection signal; and generating a compensation current based on the detection signal to reduce current flowing through a plurality of paths between the plurality of cells and the plurality of control circuits. 12. The method of claim 11 , further comprising: repeating the detecting and generating operations until the battery module enters a balanced working state, wherein in the balanced working state there is no current flowing through the plurality of paths between the plurality of cells and the plurality of control circuits. 13. The method of claim 11 , wherein if the detection signal indicates that the second consumed current is greater than the first consumed current, then a first control circuit generates a first compensation current such that the sum of the first consumed current and the first compensation current is equal to a target total current. 14. The method of claim 11 , wherein if the detection signal indicates that the first consumed current is greater than the second consumed current, then a second control circuit generates a second compensation current such that the sum of the second consumed current and the second compensation current is equal to a target total current. 15. The method of claim 11 , wherein the detection signal is generated by a detection unit coupled between the first control circuit and the second control circuit, and wherein the detection unit comprises two diodes connected back-to back in parallel. 16. The method of claim 15 , wherein the detection signal is generated by detecting voltages at the two diodes. 17. A system comprising: a first control circuit coupled to a first cell of a battery pack, the first control circuit comprising: a first control unit operating with a first consumed current; and a first compensation unit, coupled to the first control unit, that is operable for generating a first compensation current such that the sum of the first consumed current and the first compensation current is equal to a target total current, and a second control circuit coupled to a second cell in series with the first cell, the second control circuit comprising: a second control unit operating with a second consumed current; and a second compensation unit, coupled to the second control unit, that is operable for generating a second compensation current such that the sum of the second consumed current and the second compensation current is equal to the target total current. 18. The system of claim 17 , wherein the first compensation unit and the second compensation unit each comprises: a first compensation branch operable for generating a first branch current; and a second compensation branch operable for generating a second branch current, wherein the sum of the first branch current and the second branch current is equal to the compensation current of the corresponding control circuit. 19. The system of claim 17 , wherein the first control circuit and the second control circuit are coupled to a detection unit, wherein the detection unit is operable for generating a detection signal indicative of a difference between the first consumed current and the second consumed current, and wherein the first control circuit is operable for generating the first compensation current based on the detection signal, and wherein the second control circuit is operable for generating the second compensation current based on the detection signal.