Operating method and coil arrangement for a magnetic sensor for detecting metallic objects in a subgrade

What is claimed is: 1. A coil arrangement for a magnetic sensor for detecting metallic objects in a subgrade medium, comprising: a first main coil, having a winding plane to a magnetomotive force that is aligned in a vertical direction relative to a movement surface of the magnetic sensor over the subgrade medium that is largely parallel to the movement surface of the magnetic sensor; at least two coils of a first coil group arranged in an interior of an expanded winding cylinder of the first main coil between an upper edge and a lower edge of a coil body of the first main coil; and at least two coils of a second coil group arranged in the interior of the expanded winding cylinder of the first main coil, wherein the at least two coils of the second coil group have a different alignment of a winding plane as compared to a winding plane of the at least two coils of the first coil group. 2. The coil arrangement according to claim 1 , wherein the at least two coils of the first coil group are spaced apart equally from a main axis of the first main coil. 3. The coil arrangement according to claim 1 , wherein the at least two coils of the second coil group are spaced apart equally from a main axis of the first main coil. 4. The coil arrangement according to claim 1 , wherein the winding plane of the at least two coils of the second coil group is aligned perpendicular to the winding plane of the at least two coils of the first coil group. 5. The coil arrangement according to claim 1 , wherein the winding plane of the at least two coils of the first coil group is aligned parallel to the winding plane of the first main coil. 6. The coil arrangement according to claim 1 , wherein the winding plane of the at least two coils of the second coil group is aligned perpendicular to the winding plane of the first main coil. 7. The coil arrangement according to claim 1 , wherein the first main coil is a rotationally symmetrical flat coil. 8. The coil arrangement according to claim 1 , wherein the first coil group includes four coils of a same size, which are arranged at a respective angular distance of 90° and equally spaced apart from a main axis of the first main coil. 9. The coil arrangement according to claim 8 , wherein the four coils of the first coil group have winding planes which are parallel to the winding plane of the first main coil. 10. The coil arrangement according to claim 9 , wherein two of the four coils of the first coil group are arranged respectively into coil pairs opposite from one another and connected electrically in such a way that magnetic fields of the two coil pairs flow through a metallic object laterally in two directions that are orthogonal to each other. 11. The coil arrangement according to claim 9 , wherein the four coils of the first coil group are wound ovally with respective opposing pairs having a same alignment of an auxiliary axis of a coil oval. 12. The coil arrangement according to claim 1 , wherein the second coil group includes four coils of a same size, which are situated in relation to one another at a same distance from a main axis of the first main coil. 13. The coil arrangement according to claim 12 , wherein winding planes of the four coils of the second coil group are each perpendicular to the winding plane of the first main coil. 14. The coil arrangement according to claim 13 , wherein the four coils of the second coil group are arranged inside the at least two coils of the first coil group with respectively a same distance symmetrically to the main axis of the first main coil. 15. The coil arrangement according to claim 1 , further comprising a second main coil having a winding plane parallel to the winding plane of the first main coil and wherein the second main coil is arranged above the first main coil relative to the movement surface. 16. The coil arrangement according to claim 1 , wherein several of the coil arrangements are arranged in an in-line arrangement. 17. The coil arrangement according to claim 1 , wherein several, respectively grouped-alike coils of the first and/or second coil groups are arranged in an in-line arrangement, wherein the first main coil surrounds the in-line arrangement. 18. The coil arrangement according to claim 15 , wherein a diameter of the second main coil is smaller or larger than a diameter of the first main coil. 19. A method for operating a coil arrangement, wherein the coil arrangement includes: a first main coil, having a winding plane to a magnetomotive force that is aligned in a vertical direction relative to a movement surface of the magnetic sensor over the subgrade medium that is largely parallel to the movement surface of the magnetic sensor; a second main coil having a winding plane parallel to the winding plane of the first main coil, and wherein the second main coil is arranged above the first main coil relative to the movement surface; at least two coils of a first coil group arranged in an interior of an expanded winding cylinder of the first main coil; and at least two coils of a second coil group arranged in the interior of the expanded winding cylinder of the first main coil, wherein the at least two coils of the second coil group have a different alignment of a winding plane as compared to a winding plane of the at least two coils of the first coil group; wherein to localize deep lying objects, the coil arrangement is operated monostatically in accordance with “energize first main coil and read out” and bistatically in accordance with “energize first main coil and read out first coil group”; wherein for detecting grates and permeable subgrades, the coil arrangement is operated monostatically in accordance with “energize first main coil and read out” and monostatically in accordance with “energize first coil group and read out first coil group”; wherein for localizing lattice bars, the first coil group is operated monostatically in accordance with “energize first coil group and read out first coil group”; wherein for precisely localizing metallic objects, the coil arrangement is operated bistatically in accordance with “energize first main coil and read out second coil group”; wherein for a first depth of cover measurement of metallic objects, the coil arrangement is operated monostatically in accordance with “energize first main coil and read out” and monostatically in accordance with “energize second main coil and read out” and the two measuring results are analyzed ratiometrically; wherein for a second depth of cover measurement of metallic objects, the coil arrangement is operated monostatically in accordance with “energize first main coil and read out” and bistatically in accordance with “energize first main coil and read out second coil group”; wherein for a third depth of cover measurement of metallic objects, the first coil group is operated monostatically in accordance with “energize first coil group and read out first coil group”; wherein for a fourth depth of cover measurement of metallic objects, the coil arrangement is operated bistatically in accordance with “energize first coil group and read out second coil group”; wherein the first coil group includes at least two coil pairs and for an orientation measurement of metallic objects, the first coil group is operated bistatically in an alternating manner, with energizing of one of the coil pairs and detection via one other of the coil pairs or vice versa; wherein a first monostatic operation of the first coil group includes simultaneously energizing and reading out the coils of the