DE102006038036A1 - Transponder device for use in immobilizer of e.g. car, has primary coil winding in receiving device for receiving transmission device, and secondary coil winding, which is deactivated, if transmission device is outside receiving device - Google Patents

Abstract

The device (1) has a primary coil winding (4) in a receiving device (2) for receiving a transmission device (3), which has a secondary coil winding (10). The primary coil winding induces a measurable supply current (IV) in a power supply in the transmission device which flows into the secondary coil winding. The secondary coil winding is deactivated by a unit and/or with another unit, if the transmission device is outside the receiving device. The latter unit shields a magnetic field of the supply current, if the transmission device is in the receiving device.

Description

The The present invention relates to a transponder device of a power supply for a transponder device is made inductively. Furthermore, the Invention an immobilizer for a vehicle.

at Immobilizers, especially for Motor vehicles are usually inductively powered transponders used. In this case, a transponder is a mostly wireless communication display or control device, which receives a command signal and respond to it automatically. In use with immobilizers a control device of the motor vehicle transmits a release command wirelessly to the transponder, which is usually in integrated an ignition key is, whereupon the transponder sends back an authorization signal. The respective control device takes this authorization signal and then causes a release to the further engine control and gives, for example, the ignition free.

Usually Inductive powered transponders are used. This results a limited one Communication area for transmission of data between the transponder in the ignition key and the control of the respective immobilizer. However, it is still conceivable that the transponder is inductively powered by an external third magnetic field Power and then its authorization code automatically dispatches. Unauthorized third parties can then intercept and save the authorization code.

For general explanation of the problem is in the 1 a typical arrangement for an immobilizer shown. There is a lock S, for example, an ignition lock provided, in which an ignition key K is to be introduced. In order for the ignition to be released, an immobilizer control WF, which has a control unit SE, a transceiver TM, to which an antenna AT1 is coupled, must first generate a magnetic field via a coil SP1. In the handle of the key K, a transponder TP is provided with an antenna AT2, which is supplied with power by a power supply circuit ES, which is connected to a secondary coil SP2. By the magnetic field generated by the primary coil SP1 current is induced in the secondary coil SP2 as in a transformer, which serves the power supply of the transponder TP. The immobilizer control WE is supplied with energy, for example via the car battery BAT.

Provided the key K nearby the magnetic field of the primary coil SP1 and the transceiver TM via the antenna AT1 a release code sends to the transponder TP, which receives this via the antenna AT2, sends the Transponder TP automatically returns an authorization signal. in principle Is it possible, that of a third device, a correspondingly strong magnetic field is generated, so that the transponder TP in the key K also outside of the ignition S is activated and its authorization signal is canceled. Thereby it would a third party, eg. B. a potential vehicle thief, allows recognize and copy the authorization signal to later the Immobilizer to overcome the respective motor vehicle.

In In the past, therefore, communication between one Transponder of an ignition key and To control an immobilizer, a bidirectional infrared interface used. This is due to the directional property of the infrared radiation and their short range an unauthorized reading of the respective Prevents transponders. Disadvantageous when using infrared interfaces However, that is an additional communication interface for the infrared transmission both in the ignition key as well must also be provided on the vehicle side and that in particular its own, for example, battery-powered power supply in the key must be kept. This is a corre sponding solution a directed infrared interface expensive and impractical for use in mass products like ignition keys.

It It is therefore an object of the present invention to provide a transponder device specify when unauthorized reading or listening to the transponder signals is prevented.

These Task is by a transponder device with the features of claim 1.

Accordingly, a Transponder device provided which at least a first Primärspulenwindung in a receiving device for receiving a transmitting device and the at least one first secondary coil turn in the transmitting device provides. In this case, a tappable to the Sekundärspulenwindung Supply current for powering a transponder device in the transmitter from the primary coil turn into the secondary coil turn inducible. It is also a first means for deactivating the Sekundärspulenwindung provided if the transmitting device outside the receiving device is and / or a second means is provided, which is a magnetic field that of the primary coil turn in the secondary coil turn shielded induced supply current, if the transmitting device in the receiving device is.

The Invention provides that by the first means reliably the Power or voltage supply of the transponder device deactivated or is prevented as soon as the transmitting device is no longer within or partially inserted within the receiving device. As a first means, for example, comes a switch for opening and closing the Sekundärspulenwindung in question, for example, a button on the key handle may be arranged, the only by operation of the owner, the Sekundärspulenwindung includes and the power supply of the transponder allows. Furthermore, magnetic field-controlled Switch conceivable, such. B. a reed contact which the Sekundärspulenwindung only then closes, when a control magnetic field as a static magnetic field at a given Place, z. B. the key handle, prevails.

On the one hand is guaranteed that the transponder or its power supply only under control of the key owner can be active and on the other hand a potential vehicle thief just under most accurate knowledge of Schaltmittelgeometrie, for example at Using a reed contact the required geometry of the control magnetic field, the key or the transceiver could activate reserved transponder. A readout or activating the transponder signal without direct power over the Transmitting device is practically impossible.

Preferably the receiving device has at least one second primary coil turn, which is opposite to the magnetic field of the first primary coil turn Magnetic field generated. In this case, the second means has at least one second Sekundärspulenwindung which is arranged such that one of the second Primärspulenwindung in the second secondary coil turn induced current flows opposite to the supply current. there is the direction of the supply current through the induction, ie the geometry and temporal change the magnetic field of the primary coil turn Are defined. One out of the secondary coil turns constructed secondary coil in the transmitting device thus acts practically compensating for the primary coil, which from the primary coil turns is formed. This results in a non-negligible coupling factor between the two coils only locally, so close to each other in the two coils.

For example is a first and a second Primärspulenwindung such in the Receiving device arranged, and it is a first and a second Sekundärspulenwindung arranged in the transmitting device such that the first and second th Primary coil windings and the first and second secondary coil turns respectively in the type of a two-wire line. Here are one of the first primary coil turn generated magnetic field and one generated by the second Primärspulenwindung Magnetic field outside the receiving device substantially.

By suitable winding of the primary coil turns and the secondary coil turns This results in special geometries of non-vanishing Magnetic fields, in particular the Primärspulenwindung, so only a geometrically adapted secondary coil turn a noteworthy Induction current can supply as a supply current. According to the invention thus becomes a key-lock principle also to the geometric arrangement and execution of the primary and secondary coil winding to form a transformer for the energy supply of Transponder device applied.

Preferably is a respective Sekundärspulenwindung and a respective primary coil turn in an inserted state of the transmitting device in the receiving device spatial adjacent to. D. h., The windings of the primary coil preferably have over the Whole winding an equal distance to the respective secondary coil winding.

In a particularly preferred embodiment is a respective Sekundärspulenwindung within a cross section of a respective primary coil turn before, provided the transmitting device used in the receiving device is. Under cross-section in this context is the one of Coil winding enclosed surface Understood. It is therefore an embodiment conceivable in which an outer Primärspulenwindung having a common coil axis with the secondary coil turn, wherein in pairs opposite windings are present.

In one embodiment of the transponder device, a geometry of a primary coil with primary coil windings in the receiving device and a geometry of the secondary coil with secondary coil windings in the transmitting device are adapted to each other such that each first secondary winding is associated with a second secondary winding adjacent. In this case, a respective associated second secondary winding has an induced current which flows in the opposite direction to the current induced in the first secondary winding. As a result, it is achieved, in particular, that a power supply of the transponder device is possible only if the two coil geometries are matched exactly. When using any Primärspulenwindung or deviating from the given geometry induction field, the respective windings compensate each other, so no power supply possible is.

According to one another embodiment the transponder device is a geometry of a primary coil with Primary coil windings and a primary coil core in the receiving device and a geometry of a secondary coil with Secondary coil windings and a secondary coil core in the transmitting device adapted to each other in such a way that in one inserted state of the transmitting device in the receiving device an exit surface an induced magnetic field of the primary coil core or the secondary coil core an entrance area an induced magnetic field of the secondary coil core or the primary coil core arranged opposite is.

Thereby is achieved that in the primary coil core and in the secondary coil core induced magnetic fields substantially only within the nuclei run and only at the interfaces or exit and entry surfaces between the cores a magnetic field outside, between the Transmitting device and the receiving device is present. It takes place thus shielding the generated fields that are not in the environment can scatter. In a possible geometric design of the primary coil core and / or the secondary coil core as E-shaped Cores trained.

Preferably the receiving device has a slot for accurately fitting recording the transmitting device, wherein the insert in particular as a lock and the transmitting device are designed in particular as a key.

In a development of the invention is an immobilizer for a vehicle provided with a corresponding transponder device, wherein the Transponder device during activation of the power supply by the induction of the supply current, a release request receives and sends an authorization signal.

Further advantageous embodiments of the invention are the subject of the dependent claims and the in the following described embodiments. The invention will now be described with reference to preferred embodiments with reference closer to the figures explained. It shows:

1 a general representation of an immobilizer with a transponder device;

2 a first embodiment of the transponder device according to the invention;

3 a second embodiment of the transponder device according to the invention;

4 a third embodiment of the transponder device according to the invention;

5 a suitable coil geometry for a transponder device according to the invention;

6 a fourth embodiment of the transponder device according to the invention;

7 a fifth embodiment of the transponder device according to the invention;

8th a sixth embodiment of the transponder device according to the invention; and

9 A seventh embodiment of the transponder device according to the invention.

In Unless otherwise specified, the figures are the same or functionally identical elements have been provided with the same reference numerals.

In the 2 is a first embodiment of the transponder device according to the invention 1 shown.

It is a recording device 2 or a lock for a transmitting device 3 or provided an ignition key. The ignition key 3 can fit exactly into the receiving device or the lock 2 introduce.

The cradle 2 has a primary coil turn 4 on, attached to a control device 5 is coupled. The control device 5 is further provided with a transceiver 6 connected to an antenna 7 is coupled and sends, for example, a release signal or a release request, as soon as the key 3 in the castle 2 sitting. The control device 5 is via a suitable control line or a data bus 8th to the engine or closing control 9 coupled to the respective vehicle, the engine or closing control controls, for example, a blockage of the ignition for the immobilizer function.

In the transmitter 3 or here the key handle is a Sekundärspulenwindung 10 provided, for example, via a ferrite core 11 with the primary turn 4 inductively coupled. At the secondary winding 10 is thus at operated primary winding 4 with an AC current supply current IV tapped. The supply current IV represents the power supply for a transponder device 12 that with the secondary coil turn 10 connected is.

Further, a switching means 13 provided by means of which the Sekundärspulenwindung 10 geöff net or can be closed. Ie. depending on the switch position 13 is an inductive power supply of the transponder device 12 possible or excluded. The desk 13 is set up so that in the inserted state of the key 3 in the castle 2 or in the receiving device a pen 14 into a hole 15 engages and a button 27 actuated. Unless the pen 14 the button 27 pressed, is the switch 13 in the closed position, so that the secondary coil turn 10 is closed and used as a secondary coil. Thus, a transformer-like circuit results from the primary winding 4 , the ferrite core 11 and the secondary turn 10 ,

Put the key 3 in the castle 2 , thus becomes the transponder device 12 inductively supplied with a supply current IV and sends after the transmitting / receiving device 6 sends over the antenna 7 a release signal by radio to an antenna 16 connected to the transponder device 12 connected is. The transponder device 12 then automatically sends an authorization signal to the transceiver 6 back, whereupon the controller 5 the motor or closing control 9 signals that the immobilizer can be canceled.

Through the switch 13 is ensured that the enable signal or an authorization signal from the transponder device 12 only sent when the key 3 sitting in the castle. An unauthorized reading or interception of the enable signal is thus excluded.

In the 3 is a second embodiment of the transponder device according to the invention 100 shown. The recording device 2 has substantially the same elements as those in the 2 illustrated embodiment, wherein the control device, the transmitting / receiving device and the motor control are not shown.

It is schematically a first primary coil turn 4 shown, which is shown in cross section. The cross sections 4a . 4b each show the flow of current, the upper winding cross-section 4a shows the current out of the display plane and the lower winding cross-section 4b means a current in the plane of representation.

In the key 3 or the transmitting device is a Sekundärspulenwindung 10 provided in the out of the primary coil 4 an induction current can be induced as supply current IV. In the circuit of the secondary coil winding 10 is a reed contact or a magnetic field-controlled switch 17 provided, which is addressed by a control magnetic field B, which by a control magnet 19 in the recording device 2 is provided as a permanent magnet, only then closed when the key 3 perfectly fitting in the lock 2 sitting.

The secondary coil turn 10 , the reed contact 17 and a capacitor 18 form a circuit to which the transponder device 12 by connecting in parallel with the capacitor 18 is coupled. Further, an antenna 16 connected to the transponder device. Similar in the 2 illustrated arrangement is due to the adapted geometry of the reed contact 17 and the permanent magnet 19 or its magnetic field B only a power supply of the transponder device 12 possible if the key 3 in the castle 2 sitting. An involuntary sending of the authorization signal by the transponder 2 is excluded.

In the 4 is a third embodiment of the transponder device according to the invention 200 shown.

It is a recording device 2 provided, which is a control device 5 and a transmitting / receiving device 6 with an antenna 7 has, wherein the control device 5 via a suitable data bus 8th to a motor or closing control 9 is coupled. Further, a first primary coil turn 4 provided, wherein in the 4 one winding cross section each 4a . 4b is shown with the associated current flow. In the recording device 2 is also a second primary coil turn 20 , also through the winding cross sections 20a . 20b shown, the two windings 4 . 20 lie next to each other in the manner of a two-wire line and rotate around the key axis AX. In the winding cross sections, a current flowing out of the display plane is indicated by the point, and a current is indicated by the cross symbol x, which flows into the display plane. There are also other primary coil turns conceivable, each adjacent turns having an opposite current flow.

The transmitting device 3 is with a first secondary coil turn 10 and a second secondary coil turn 21 equipped with the first secondary coil turn 10 parallel to the first primary coil turn 4 runs and the second Sekundärspulenwindung 21 parallel to the second primary coil turn 20 runs. Again, the windings are designed such that the respective currents of directly adjacent winding wires flow in the opposite direction.

At the first and second secondary coil turn 10 . 21 formed secondary coil 22 is the transponder device 12 via lines 28 coupled receiving the supply current IV. The transponder device 12 also has an antenna 16 for receiving a release signal from the transceiver 6 and for sending the authorization signal.

In the 5 is a spatial representation of the secondary coil 22 played. The first and second secondary coils meander 10 . 21 are arranged such that a respective induced current, which by the arrows 23 is indicated in the first secondary turn 10 opposite to the current in the second secondary winding 21 flows. This results in a two-wire line effect for the two secondary coil windings; see also the winding cross sections 10a . 10b . 21a . 21b , Similarly, the primary coil as used in the 4 is indicated concentrically around the secondary coil 22 built up. In the 5 are only the winding cross sections 4a . 4b . 20a . 20b represented with the respective current directions.

The magnetic fields generated by the coils are indicated by the arrows 24 indicated. The around the primary coil turns 4 . 20 occurring magnetic fields 24 Lift practically outside the coil area or outside of the receiving device 2 on. Only in the immediate vicinity, where the secondary coil turns 10 . 21 are provided, a current can be induced as supply current IV. The special geometry of the two matched primary and secondary coils makes it virtually impossible for induction of currents into the secondary windings 10 . 21 can be done when any induction field, for example, generated by a potential vehicle thief, for power supply, ie supply current induction is used. The in the receiving device 2 trained primary coils or in the transmitting device 3 trained secondary coils are matched to one another such that the secondary coil for a remotely located primary coil acts only compensating, whereby the respective coupling factor is practically zero. This is the case when the key 3 not in the castle 2 sitting.

In the 6 is a fourth embodiment of the transponder device according to the invention 300 shown with an alternative geometry of the primary and secondary coil turns.

The in a recording device 2 provided two Primärspulenwindungen 4 . 20 , each represented by the winding cross-sections 4a . 4b . 20a . 20b lie in the inserted state of the transmitting device 3 in the receiving device 2 directly opposite the secondary coil turns 10 . 21 , also represented by the winding cross-sections 10a . 10b . 21a . 21b , While in the embodiment according to the 4 . 5 the secondary coil windings are within the cross section of the primary coil windings, have the secondary and primary coil windings in the embodiment 300 according to the 6 via a common axis of symmetry AX, such that the first primary coil turn 4a . 4b and the first secondary coil turn 10a . 10b on the one hand or the second Primärspulenwindung 20a . 20b and the second secondary coil turn 21a . 21b on the other hand run on different coil radii. As already in the 5 is shown, the respective turns are designed such that directly adjacent turns or wires are flowed through by currents in the opposite direction of flow. That is, it is an induction of supply currents from the primary coil turns 4 . 20 into the secondary coil turns 10 . 21 only possible if the two primary and secondary coils are nestled very close together. Thus, the smallest possible distance in the inserted state of the key in the lock between the primary and secondary windings is advantageous.

In the 7 is a fifth embodiment of the transponder device according to the invention 400 shown.

It is again a recording device 2 and a transmitting device 3 provided or a lock and a key. It is a first primary coil 25a and a second primary coil 25b in the receiving device 2 intended. In the transmitter 3 are corresponding two secondary coils 26a . 26b provided in the inserted state each of the primary coils 25a . 25b are opposite. For example, the first primary coil is located 25a the first secondary coil 26a across from.

Here are the primary coils 25 and the secondary coils 26 wound in opposite directions. In other words, the respectively occurring magnetic fields in the coils, which may be equipped, for example, with ferrite cores, are raised substantially outside the receiving device 2 on.

A tapping of currents induced in the secondary coils for the power supply of the transponder device not shown here takes place practically only when the respective coordinated windings and coils 25a . 25b . 26a . 26b geometrically, as in the 7 shown, are positioned. Is the transmitting device 3 outside the recording device 2 , goes a coupling factor of the two coil pairs 25a . 26a respectively. 25b . 26b against zero.

Even a third alternating magnetic field does not lead to a sufficient current induction in the two secondary coils 26a . 26b , as these are also wound in opposite directions, which in each case by the point on the coil symbol darge is is. This is the same with the fifth embodiment 400 the transponder device 400 excluded that unintentionally in the key 3 provided transponder device is activated and outputs an authorization signal.

In the 8th is a sixth embodiment of the transponder device according to the invention 500 shown. The embodiment 500 has substantially the same elements as the third embodiment of the transponder device 200 as they are in the 4 is shown on.

For explanation, the second secondary coil turn 21 ' in the transmitting device 3 or the key shown schematically. In addition, there is a switch 13 ' provided, which via a button 27 can be operated, with the button 27 at the key handle of the key 3 is provided. By pressing the button 27 becomes the switch 13 closed and thus makes it possible by closing the secondary winding 21 ' an induction of a supply current IV in the secondary winding. Another switch, for example, for the first secondary winding 10 , see winding cross sections 10a . 10b be provided.

The embodiment 500 according to the 8th Thus, it has two security mechanisms, the read-out by external activation of a transponder device in the key 3 prevented. On the one hand, due to the matched geometry of the primary and secondary coils, only one power supply in the lock 2 allows and on the other hand allows the switch 13 a manual activation of the secondary coils and thus a power supply of the transponder, not shown here.

In the 9 is a seventh embodiment of the transponder device according to the invention 600 shown. The recording device 2 has substantially the same elements as those in the 2 illustrated embodiment, wherein the control device, transmitting / receiving device and motor control are not shown. Also on the key side, the transponder device and the antenna are not shown.

The primary coil turns 4 and the secondary coil turns 10 are each on a bobbin 28 . 29 wound, which is E-shaped, with the windings of the primary and secondary coil turns 4 . 10 each around the middle leg of the spool core 28 . 29 are wound. With the arrows 24 ' are the magnetic field directions in the respective coil core 28 . 29 designated.

In the inserted state of the key 3 in the castle 2 lies a respective exit surface 30a . 31a . 32a a magnetic field of a nucleus 28 . 29 in the environment always opposite an entrance area 30b . 31b . 32b the other core 28 . 29 , The legs of the E-shaped coil cores 28 . 29 practically encounter each other, and there is only con structurally caused a gap at the interface between the primary coil core 28 and the secondary coil core 29 ,

In In this embodiment, it is also practically impossible without exact knowledge of the coil core geometries an adapted induction magnetic field to generate a supply current in the secondary coil winding causes. A homogeneous external magnetic field, for example, would be used mainly in the outer thighs the secondary coil core are guided, so that there is no adequate field in the middle leg, to induce a significant current in the secondary winding.

By the invention is the securing of a vehicle with an immobilizer, the a transponder device according to the invention used, significantly improved. Because on the one hand can be a volitional Communication release only by the vehicle owner, if this is the key inserted into the lock and optionally additionally pressed a button. on the other hand A supply current induction occurs only when a specially to the geometry of the secondary turns adapted induction field is present. The invention is also easy to implement, there are no active elements in addition a vehicle key would have to be introduced. The elements used, such as a secondary coil and a transponder device are usually already in car keys in front.

Even though the present invention based on preferred embodiments was explained in more detail, is she not limited to but diverse modifiable. The exemplary geometries shown in the figures for the Design of the primary and secondary coil turns are only examples. Furthermore, further switching means for deactivation of the respective Sekundärspulenwindungen conceivable, provided the transmitting device or the key outside the receiving device is.

S

lock

K

key

SE

control device

SP1 SP2

Kitchen sink

TM

Transmitting / receiving device

WF

Wegfahrsperrensteuerung

AT1, AT2

antenna

BAT

battery

TP

transponder

IT

power supply

IV

supply current

B

magnetic field

AX

Key or coil axis

1, 100, 200, 300, 400, 500, 600

transponder device

2

Recording device, lock

3

Transmitting device, ignition key

4

Primärspulenwindung

5

control device

6

Transmitting / receiving device

7

antenna

8th

data line

9

Engine- or closing control

10

Sekundärspulenwindung

11

Ferrite core

12

transponder device

13

switch

14

pen

15

drilling

16

antenna

17

Reed contact

18

capacitor

19

permanent magnet

20

Primärspulenwindung

21 21 '

Sekundärspulenwindung

22

secondary coil

23

current direction

24 24 '

magnetic field direction

25 26

Ferrite coil

27

button

28

Primary core

29

Secondary coil core

30a, 31a, 32b

exit area

30b, 31b, 32a

entry surface

Claims (14)

Transponder device ( 1 ) comprising: a) at least one first primary coil turn ( 4 ) in a receiving device ( 2 ) for receiving a transmitting device ( 3 ); b) at least one first secondary coil turn ( 10 ) in the transmitting device ( 3 ), wherein a tapped supply current (IV) for supplying energy to a transponder device ( 12 ) in the transmitting device ( 3 ) from the primary coil turn ( 4 ) into the secondary coil turn ( 10 ) is inducible; and with c) a first means ( 13 ) for deactivating the secondary coil turn ( 10 ), if the transmitting device ( 3 ) outside the recording device ( 2 ) and / or with a second means ( 20 . 21 ), which has a magnetic field from that of the primary coil winding ( 4 ) into the secondary coil turn ( 10 ) shielded supply current (IV), if the transmitting device ( 3 ) in the receiving device ( 2 ). Transponder device ( 1 ) according to claim 1, characterized in that the first means ( 13 ) at least one switch ( 13 ) for opening and closing the secondary coil turn ( 10 ) having. Transponder device ( 1 ) according to claim 1 or 2, characterized in that the switch ( 13 ) is configured such that the secondary coil turn ( 10 ) is closed only and a supply current (IV) is inducible if the transmitting device ( 3 ) in the receiving device ( 2 ) is introduced. Transponder device ( 100 ) according to at least one of claims 1-3, characterized in that the first means a reed contact ( 17 ), which by means of a in the receiving device ( 2 ) generated control magnetic field (B) for activating the Sekundärspulenwindung ( 10 ) is closable. Transponder device ( 100 ) according to claim 4, characterized in that in the receiving device ( 2 ) a permanent magnet ( 19 ) is provided, the control magnetic field (B) in an inserted state of the transmitting device ( 3 ) in the receiving device ( 2 ) the reed contact ( 17 ) controls. Transponder device ( 200 . 300 ) according to at least one of the preceding claims, characterized in that the receiving device ( 2 ) at least one second primary coil turn ( 20 ), which corresponds to the magnetic field of the first Primärspulenwindung ( 4 ) generates opposite magnetic field, and wherein the second means at least one second Sekundärspulenwindung ( 21 ) which is arranged such that one of the second Primärspulenwindung ( 20 ) in the second secondary coil turn ( 21 ) induced current opposite to the supply current (IV) flows. Transponder device ( 400 ) according to at least one of the preceding claims, characterized in that a first and a second primary coil ( 4 . 20 ) in the receiving device ( 2 ) are arranged and a first and a second secondary coil ( 22 ) in the transmitting device ( 3 ) are arranged such that the first and second Primärspulwindungen ( 4 . 20 ) and the first and second secondary coil windings ( 10 . 21 ) are in the form of a two-wire line, wherein one of the first primary coil ( 4 . 20 ) generated magnetic field and one of the second primary coil ( 10 . 21 . 22 ) generated magnetic field outside the recording device ( 2 ) substantially cancel. Transponder device ( 200 . 300 ) according to at least one of the preceding claims, characterized in that in an inserted state of the transmitting device ( 3 ) in the receiving device ( 2 ) a respective secondary coil turn ( 10 . 21 ) and a respective primary coil turn ( 4 . 20 ) are spatially adjacent. Transponder device ( 200 ) according to at least one of the preceding claims, characterized in that in an inserted state of the transmitting device ( 3 ) in the receiving device ( 2 ) a respective secondary coil turn ( 10 . 21 ) within a cross section of a respective primary coil turn ( 4 . 20 ) is present. Transponder device ( 200 . 300 ) according to at least one of the preceding claims, characterized in that a geometry of a primary coil with primary coil turns ( 4 . 20 ) in the receiving device and a geometry of a secondary coil with secondary coil turns ( 10 . 21 ) in the transmitting device ( 3 ) are adapted to each other such that each first secondary winding ( 10 ) a second secondary winding ( 21 ), wherein a respective associated second secondary winding ( 21 ) has an induced current corresponding to that in the first secondary winding ( 10 ) induced current is opposite. Transponder device ( 600 ) according to at least one of the preceding claims, characterized in that a geometry of a primary coil with primary coil turns ( 4 ) and a primary coil core ( 28 ) in the receiving device ( 2 ) and a geometry of a secondary coil with secondary coil turns ( 10 ) and a secondary coil core ( 29 ) in the transmitting device ( 3 ) are adapted to one another such that in an inserted state of the transmitting device ( 3 ) in the receiving device ( 2 ) an exit surface ( 30a . 31a . 32b ) of an induced magnetic field ( 24 ) of the primary coil core ( 28 ) or the secondary coil core ( 29 ) an entrance surface ( 30b . 31b . 32a ) of an induced magnetic field ( 24 ) of the secondary coil core ( 29 ) or the primary coil core ( 28 ) is arranged opposite. Transponder device ( 600 ) according to claim 11, characterized in that the primary coil core ( 28 ) and / or the secondary coil core ( 29 ) is each formed as an E-shaped core. Transponder device ( 1 . 100 . 200 . 300 . 400 . 500 . 600 ) according to at least one of the preceding claims, characterized in that the receiving device ( 2 ) a slot for precise recording of the transmitting device ( 3 ), wherein the insert are designed in particular as a lock and the transmitting device, in particular as a key. Immobilizer for a vehicle with a transponder device ( 1 . 100 . 200 . 300 . 400 . 500 . 600 ) according to at least one of claims 1-13, wherein the transponder device ( 12 ) upon activation of the power supply by induction of the supply current (IV) receives a release request and sends an authorization signal.