Battery management unit with a PCB integrated fluxgate current sensor

What is claimed is: 1. A battery management unit for a battery system with a conductor or a busbar, the battery management unit comprising: a printed circuit board; and a fluxgate current sensor comprising: a magnetic core having a through-hole; at least one excitation winding wound around the magnetic core; at least one compensation winding wound around the magnetic core; and a sensor circuit configured to measure a magnetization of the at least one excitation winding, to generate a driving signal for driving the at least one compensation winding such that a magnetic flux in the magnetic core is cancelled out by a current in the at least one compensation winding, to generate a current flowing through the at least one compensation winding according to the driving signal, and to generate an output signal corresponding to a magnitude of an electric current flowing through the through-hole of the magnetic core; wherein the magnetic core, the at least one excitation winding, the at least one compensation winding, and the sensor circuit are each integrated into the printed circuit board, turns of the at least one excitation winding and the at least one compensation winding being entirely parallel to the printed circuit board, and wherein the magnetic core is arranged on the printed circuit board such that the battery management unit is mountable into the battery system and such that the conductor or the busbar of the battery system passes through the through-hole of the magnetic core. 2. The battery management unit according to claim 1 , wherein each of the excitation and compensation windings comprises a plurality of turns, each of the turns extending in parallel with the printed circuit board around a virtual center axis perpendicular to the printed circuit board. 3. The battery management unit according to claim 2 , wherein the printed circuit board comprises a plurality of layers, wherein the layers extend in stacked planes parallel to each other, wherein, for each winding of the at least one excitation winding and the at least one compensation winding, at most one turn extends per layer of the layers, and wherein, for each winding of the at least one excitation winding and the at least one compensation winding, any two consecutive turns are connected to each other such that an entirety of the turns forms the winding. 4. The battery management unit according to claim 2 , wherein, for each winding of the at least one excitation winding and the at least one compensation winding, the turns of the winding are arranged at one layer of the printed circuit board to form a flat spiral. 5. The battery management unit according to claim 2 , wherein the printed circuit board comprises a plurality of layers, wherein the layers extend in stacked planes parallel to each other, wherein each winding of the at least one excitation winding and the at least one compensation winding comprises flat spiral windings arranged at all or a subset of the layers, and wherein, for each winding of the at least one excitation winding and the at least one compensation winding, any two neighboring flat spiral windings are connected to each other such that an entirety of the turns forms one winding. 6. The battery management unit according to claim 1 , wherein the magnetic core is, apart from the through-hole, shaped as a cuboid. 7. The battery management unit according to claim 1 , wherein the through-hole has a rectangular cross-sectional shape, a polygonal cross-sectional shape, an elliptical cross-sectional shape, or a circular cross-sectional shape. 8. The battery management unit according to claim 1 , wherein the magnetic core passes through holes in the printed circuit board. 9. The battery management unit according to claim 8 , wherein a number of holes in the printed circuit board is two, and wherein the magnetic core comprises two U-shaped parts being shaped to pass through the holes in the printed circuit board. 10. The battery management unit according to claim 9 , wherein the two U-shaped parts of the magnetic core are configured to be held together by one or more spring brackets, by an adhesive, or by a housing of the battery management unit. 11. The battery management unit according to claim 1 , wherein the printed circuit board comprises two neighboring layers, wherein the magnetic core is flat and located between the two neighboring layers, wherein each of the two neighboring layers of the printed circuit board has a through-hole of a plurality of through-holes, wherein the through-hole of the magnetic core and the through-holes of the two neighboring layers are located to accommodate a conductor or a busbar passing through any one of said through-holes along a virtual center axis perpendicular to the printed circuit board, and wherein, for each one of the excitation and compensation windings, one half of each complete turn is arranged at one of the two neighboring layers and an other half of each complete turn is arranged on an other of the two neighboring layers. 12. The battery management unit according to claim 11 , wherein the magnetic core has a rectangular shape, a square shape, an elliptical shape, or a circular shape. 13. The battery management unit according to claim 11 , wherein each of the through-hole in the magnetic core and the through-holes in the two neighboring layers of the printed circuit board has a rectangular shape, a square shape, an elliptical shape, or a circular shape. 14. A battery system comprising: the battery management unit according to claim 1 ; and a conductor, wherein the conductor is passed through the through-hole of the magnetic core.