Efficient passive broadband gyrator

The invention claimed is: 1. A gyrator for AC signals, comprising a Hall effect material, means for coupling an alternating current (I 1 ; I 4 ) into the Hall effect material, means for permeating the Hall effect material with a magnetic field that is perpendicular to the plane or surface of the material, means for converting a current (I 3 ; I 2 ), which was generated by the current I 1 perpendicularly to the electric field generated by I 1 in the Hall effect material, into an output voltage (U 4 ; U 1 ), wherein a transformer provided between at least one conductor loop made of a normal-conducting or semi-conducting material and at least one conductor loop made of the Hall effect material for coupling the current (I 1 ; I 4 ) into the Hall effect material and/or for converting the current (I 3 ; I 2 ) in the Hall effect material into the output voltage (U 4 ; U 1 ), and the Hall effect material is disposed in at least two segments such that, when a magnetic field is applied, an electromotive force in one segment produces a current flow primarily in the other segment. 2. The gyrator according to claim 1 , comprising a second transformer between at least one other conductor loop made of a normal-conducting or semi-conducting material and at least one other conductor loop made of the Hall effect material for coupling the current (I 1 ; I 4 ) into the Hall effect material and/or for converting the current (I 3 ; I 2 ) in the Hall effect material into the output voltage (U 4 ; U 1 ), wherein the conductor loops of the two transformers, which are made of the normal-conducting or semi-conducting material, are inductively decoupled from each other. 3. The gyrator according to claim 2 , wherein the Hall effect material forms at least two conductor loops ( 1 ) and ( 2 ), which are electrically connected to each other at one point and intersect without electrical connection at least at one other point. 4. The gyrator according to claim 3 , wherein the one conductor loop ( 1 ; 2 ) is the secondary winding of one of the two transformers, said one of the two transformers being configured for incoupling the input current (I 1 ; I 4 ) and/or the second conductor loop ( 2 ; 1 ) is the primary winding of the transformer other of the two transformers, said other of the two transformers being configured for converting the current (I 3 ; I 2 ) in the Hall effect material into the output voltage (U 4 ; U 1 ). 5. The gyrator according to claim 3 , wherein the one conductor loop ( 1 ; 2 ) is the secondary winding of one of the two transformers, said one of the two transformers being configured for incoupling the input current (I 1 ; I 4 ) and/or the second conductor loop ( 2 ; 1 ) is the primary winding of the other of the two transformers, said other of the two transformers being configured for converting the current (I 3 ; I 2 ) in the Hall effect material into the output voltage (U 4 ; U 1 ). 6. The gyrator according to claim 1 , wherein the Hall effect material is a quantum Hall effect material. 7. The gyrator according to claim 6 , wherein the quantum Hall effect material comprises graphene and/or a semiconductor heterostructure, which forms a two-dimensional electron gas. 8. The gyrator according to claim 1 , wherein the Hall effect material forms at least two conductor loops ( 1 ) and ( 2 ), which are electrically connected to each other at one point and intersect without electrical connection at least at one other point. 9. The gyrator according to claim 1 , wherein the Hall effect material comprises a metalloid, in particular a metalloid from the group arsenic, α-tin (gray tin), antimony, bismuth or graphite, and/or a doped semiconductor. 10. The gyrator according to claim 1 , wherein the Hall effect material occupies a three-dimensional area, which can be represented by moving a two-dimensional area on a closed path in the space. 11. The gyrator according to claim 10 , wherein the Hall effect material is disposed as a layer on an insulating substrate and/or the three-dimensional area forms a hollow body from the Hall effect material. 12. The gyrator according to claim 11 , wherein one path in the Hall effect material, along the closed path or parallel to this path, is the secondary winding of the transformer for incoupling the input current (I 1 ; I 4 ), or the primary winding of the transformer for converting the current (I 3 ; I 2 ) in the Hall effect material into the output voltage (U 4 ; U 1 ). 13. The gyrator according to claim 10 , wherein one path in the Hall effect material, along the circumference of the two-dimensional area, at a point on the closed path, is the secondary winding of the transformer for incoupling the input current (I 1 ; I 4 ), or the primary winding of the transformer for converting the current (I 3 ; I 2 ) in the Hall effect material into the output voltage (U 4 ; U 1 ). 14. The gyrator according to claim 10 , wherein the three-dimensional area is a torus. 15. The gyrator according to claim 10 , wherein the Hall effect material has at least one opening for feeding magnetic field lines through the three-dimensional area. 16. The gyrator according to claim 10 , comprising a magnetic multipole arrangement for permeating the Hall effect material with the magnetic field. 17. The gyrator according to claim 10 , further comprising means for generating a local electric auxiliary field in at least one location in the three-dimensional area. 18. The gyrator according to claim 1 , wherein the Hall effect material is a material having a Hall angle θ H of at least 80 degrees at a magnetic field strength of 1 T.