DE19937086A1 - Electronic lock system, esp. ignition lock system for motor vehicle, has code transfer arrangement operated at different optical frequency from energy transmission frequency - Google Patents

Abstract

The system has an electronic lock (3) and key (2), an arrangement for optically transferring energy from the lock to the key to operate the key and an arrangement for the optical transfer of a code between the lock and key. After positive identification of the code, at least one action is performed in and/or by the lock, such as triggering functions, switching on the ignition, starting the engine, etc. The code transfer arrangement can be operated at an optical frequency that is different in at least one transmission direction (4) between the key and lock from the energy transmission (12) frequency.

Description

The invention relates to an electronic locking system, in particular an ignition lock system for a motor vehicle, according to the preamble of Claim 1.

Ignition lock systems of this type are used in motor vehicles for this purpose Installation. For example, it can be the release of certain functions, switching on the ignition, starting act o. The like of the motor vehicle.

EP 0 720 545 B1 describes an electronic ignition lock system for a motor vehicle known that consists of an electronic lock and an electronic key. The ignition lock system has Means for the contactless transmission of energy from the castle to the Key so that the key in the lock can be locked using the transferred energy can be operated as intended. Are further Means for transmitting a code between the lock and the Key available, after positive evaluation of the transmitted  Codes at least one action in and / or through the lock Commissioning of the motor vehicle can be triggered. Both in the Means for energy transmission as well as the means for Code transmission can be inductive and / or optically working Act means.

Both energy and code transmission occurs on optical ways, so there can be mutual interference between the two Transfers occur. This in turn leads to malfunction of the Ignition lock system. Therefore, it is for this case during the Code transmission necessary to suspend energy transmission. This complicates the operation of the ignition lock system and requires one elaborate energy control, so the key to its operation enough energy is available. It also extends thereby the duration for the code transmission.

The invention has for its object the ignition lock system in such a way further develop that simultaneous energy and Code transmission is possible optically.

This task is carried out in a generic ignition lock system the characterizing features of claim 1 solved.

In the solution according to the invention, the means for code transmission are operable with an optical frequency, which in at least one Direction of transmission between the lock and the key  is different from the optical frequency of the energy transmission. There is a mutual influence of energy and code transmission thereby effectively prevented. Further refinements of the invention are the subject of the subclaims.

So the means of energy transfer from the castle to the Keys work by means of laser radiation, which is particularly important Offers infrared laser radiation. The means of energy transmission expediently consist of one located in the castle Laser diode, such as a GaAlAs laser diode, and one in the key located solar cell.

The means for code transmission preferably work in Direction of transmission from the key to the lock with a higher one Frequency as the means of energy transmission. In particular receives you have a sufficient frequency separation from infrared laser radiation, if at least green optical radiation is used for this. The Means for code transmission in the direction of transmission from the key on the lock consist of electro-optical transducer elements, for example from light emitting diodes and / or photo transistors. At Use of green optical radiation is preferred green LEDs for both sending and receiving the code used. Green light-emitting diodes advantageously have a particularly narrow-band sensitivity to green light and are therefore completely insensitive to infrared radiation. A disturbance of the Code transmission by infrared laser radiation is consequently included  Prevents security. In the direction of transmission from the castle to the Keys can be used as a means of code transmission at the same time Means of energy transmission can be used by the to transmitting code of the laser radiation is modulated.

So that the lock for the user like a conventional ignition lock is operable, it has one in the manner of a rotor trained receptacle with an insertion opening for the electronic Key. The resources associated with the castle for energy and Code transmission is at the opposite of the insertion opening Side of the recording arranged while the key assigned Means for energy and code transmission on the front of the in the Recording part of the key are arranged. Thereby are the means of energy and code transmission in the key and in Closed facing each other, which is an effective energy and Code transmission guaranteed. The efficiency can continue through this be increased so that the solar cell is of such a size, that the radiation emitted by the laser diode in all Rotor positions of the recording is covered by the solar cell.

In a further embodiment, the means for energy and Code transmission in the lock, such as the laser diode and the green one Light-emitting diode, attached to a bracket, which is in the manner of a Stator is formed. The bracket protrudes into the rotor. At the same time, the holder serves as a heat sink for the laser diode. Of course, the chips for the laser diode and the  Light-emitting diode can also be bonded to a common substrate. The Means of energy and code transmission in the key, like that The solar cell and the green LED are on a circuit board attached. The circuit board is inside the in the recording located part of the key.

To prevent laser radiation from escaping, there is one at the lock Device for closing the insertion opening when removed Keys arranged. This facility has flaps that at Insertion of the key in the spring loaded receptacle are laterally movable away. When removing the key from the The flaps are automatic due to the spring force resettable.

To operate the laser diode is in the castle accordingly Embodiment arranged a laser driver circuit. The Laser driver circuit contains a switching voltage regulator, the output voltage is fed to a modulation circuit. In the modulation circuit is a power semiconductor, like a MOS-FET or the like, arranged, which corresponds to that of the castle on the Key to be transmitted code the current supplied to the laser diode modulated. Next is a receiving circuit with a in the castle LED for the one to be transferred from the key to the lock Code arranged. The receiving circuit contains an impedance converter to stabilize the voltage emitted by the LED. The Impedance converter is an amplification circuit for the output  Voltage connected downstream, the increased voltage then a comparator for level adjustment is supplied.

According to one embodiment, the key contains a Voltage stabilization circuit for stabilizing the of the Solar cell output voltage arranged to operate the Key with the key in the holder. Further there is a demodulation circuit in the key for Filtering out and amplifying the code transmitted by the lock the voltage emitted by the solar cell.

The advantages achieved with the invention are in particular that no elaborate control of the lock on the key transmitting energy is necessary. Because corresponding Control circuits are not required overall an inexpensive locking system.

Rather, there is an uninterrupted energy transfer to the Key when the key is in the lock, so always sufficient energy is available to operate the key. Failure situations that otherwise due to lack of energy are effectively prevented. Besides, one is Code transmission disrupted by energy transmission excluded, so that the locking system according to the invention very much works reliably.  

Since the code transmission takes place parallel to the energy transmission, the duration of the code transmission is also shortened. This also increases the security of the locking system against misuse considerably.

An embodiment of the invention with different Further developments is shown in the drawings and is in following described in more detail. Show it

Fig. 1 shows schematically a functional overview to an electronic locking system in a motor vehicle,

Fig. 2 is a block diagram for power and code transmission between the lock and the key,

Fig. 3 is a timing diagram for the power and code transmission,

Fig. 4 shows a longitudinal section through the lock,

Fig. 5 shows the key in partial section,

Fig. 6 is a block diagram of the circuit for energy transmission and code broadcast in the lock,

Fig. 7 is a block diagram for the circuit for code reception in the castle and

Fig. 8 is a block diagram for the energy and code transmission in the key.

In Fig. 1, an electronic locking system 1 intended for a motor vehicle is shown schematically according to part of its functions. The locking system 1 comprises an ignition lock system for starting up the motor vehicle and consists of an electronic lock 3 and an electronic key 2 , the key 2 being insertable into the lock 3 designed as an ignition lock. In the lock 3 and in the key 2 there are means for the contactless optical transmission of a code 4 between the lock 3 and the key 2 . In this case, bidirectional communication preferably takes place by exchanging the code 4 in both transmission directions 4 ′, 4 ″ between the lock 3 and the key 2 . However, the code 4 can also be exchanged only in one transmission direction 4 ', in particular from the key 2 to the lock 3 . After positive evaluation of the transmitted code 4 , at least one action 6 can be triggered in and / or by the lock 3 . For example, this can involve enabling functions for the motor vehicle, switching on the ignition of the motor vehicle, starting the motor vehicle or the like.

In addition, the access authorization to the motor vehicle can be controlled remotely using the key 2 . For this purpose there are actuators 7 on the key 2 , which the user actuates manually. As a result, a code 5 can be transmitted between the key 2 and a receiving device 9 arranged, for example, centrally on the inside mirror 8 in the motor vehicle. After positive evaluation of the code 5 , ie if it is the authorized key 2 , a control device 10 is actuated to lock or unlock the car doors 11 , the trunk lid or the like.

The key 2 has an energy storage device, not shown, which supplies the key 2 with a voltage for operating the remote control for the access authorization. To protect the energy storage, however, the key 2 is supplied with energy from the lock 3 for the operation of the key 2 in the ignition lock system, where the key 2 is located in the lock 3 . For this purpose, means are provided for the optical transmission of energy 12 from the lock 3 to the key 2 , as is shown schematically in FIG. 2, so that the key 2 can be operated by means of the energy 12 transmitted.

The means for transmitting the code 4 can be operated with an optical frequency which is different from the optical frequency of the energy transmission 12 in at least one transmission direction 4 ″ between the key 2 and the lock 3 . Mutual interference between the optical energy transmission 12 and the code transmission 4 is thus effectively prevented. In particular, it should be emphasized that an interruption of the energy transmission 12 during the code transmission 4 ″ from the key 2 to the lock 3 is therefore not necessary, as can also be seen from FIG. 3.

In order to ensure a particularly effective energy transmission 12 , it is preferred that the means for energy transmission 12 work from the lock 3 to the key 2 by means of laser radiation. In particular, it can be infrared laser radiation. Then it makes sense to arrange a laser diode 13 as a means for energy transmission 12 in the lock 3 , as can be seen in FIG. 2. For example, a GaAlAs laser diode can be used that generates the desired infrared laser radiation. In the key 2 there is a solar cell 14 as a means of energy transfer 12th

In the direction of transmission 4 'from the lock 3 to the key 2 , the means for code transmission 4 preferably consist of the means for energy transmission 12 . For this purpose, the code 4 ′ to be transmitted is then modulated onto the laser radiation, as can be seen from FIGS. 2 and 3.

According to a further embodiment, the means for code transmission 4 in the transmission direction 4 ″ from the key 2 to the lock 3 work at a higher frequency than the means for energy transmission 12 . In order to ensure a sufficient distance from the infrared radiation of the energy transmission 12 , the code transmission 4 ″ takes place at least with green optical radiation. Electro-optical transducer elements, which can be, for example, light-emitting diodes, photo transistors or the like, are used as means for code transmission 4 in the transmission direction 4 ″ from the key 2 to the lock 3 . In particular, the electro-optical converter elements consist of green light-emitting diodes 15 , 15 'which are used both in the key 2 as light-emitting diode 15 for emitting green optical radiation when a voltage is applied, and conversely in lock 3 as light-emitting diode 15 ' for converting green optical radiation into voltage can.

As can further be seen from FIG. 4, the lock 3 has a receptacle 17 designed in the manner of a lockable rotor 16 with an insertion opening 18 for the electronic key 2 . If the key 2 is in the receptacle 17 and the code transmission 4 between the key 2 and the lock 3 is positive, the rotor 16 is released by unlocking. Then the rotor 16 can be moved into different rotor positions by means of the key 2 , in which, for example, electrical consumers in the motor vehicle can be switched on, the ignition is switched on and the engine is started.

The means for energy transmission 12 and code transmission 4 assigned to the lock 3 , namely the laser diode 13 and the light-emitting diode 15 'not visible in FIG. 4, are arranged on the side of the receptacle 17 opposite the insertion opening 18 , specifically on one Bracket 19 attached. The holder 19 is designed in the manner of a stator which projects into the rotor 16 . At the same time, the holder 19 serves as a heat sink for the laser diode 13 . To simplify assembly, it may be advisable to bond the chips for the laser diode 13 and the light-emitting diode 15 'to a common substrate, which is then attached to the holder 19 .

Furthermore, the means for energy transmission 12 and code transmission 4 assigned to the key 2 , namely the solar cell 14 and the green light-emitting diode 15 , are arranged on the front 20 of the part 22 of the key 2 which can be inserted into the receptacle 17 , as shown in FIG . 5 can be seen. The solar cell 14 and the light-emitting diode 15 are fastened on a printed circuit board 21 . The circuit board 21 is arranged within the part 22 of the key 2 .

If the key 2 with its part 22 is located in the receptacle 17 , then the means for energy transmission 12 and code transmission 4 in the key 2 and in the lock 3 face each other, thus increasing the efficiency of the energy and code transmission 12 , 4 is guaranteed. Since the rotor 16 can be rotated into different rotor positions by means of the key 2 , it is expedient if the solar cell 14 has such a size that the radiation emitted by the laser diode 13 is covered by the surface of the solar cell 14 in all rotor positions of the receptacle 17 .

In order to prevent the laser radiation from escaping from the lock 3 for security reasons, a device for closing the insertion opening 18 into the receptacle 17 with the key 3 removed is arranged on the lock 3 . This device has flaps 23 , which can be moved laterally when the key 2 is inserted under spring loading, as shown in FIG. 4 with the further position of the flaps 23 . When the key 2 is removed, the flaps 23 can then be automatically reset due to the spring force.

The electrical circuit for operating the lock 3 can be seen in more detail in FIGS. 6 and 7 as a basic block diagram. As can be seen from Fig. 6, is in the lock 3 with the lock electronics 24 , the circuits for generating and decoding the code 4 u. Like. Contains, connected laser driver circuit 25 for driving the laser diode 13th The laser driver circuit 25 comprises a switching voltage regulator, the output voltage of the laser driver circuit 25 being fed to a modulation circuit 26 . A power semiconductor, for example a MOS-FET or the like, is arranged in the modulation circuit 26 . The power semiconductor modulates the current supplied to the laser diode 13 in accordance with the code to be transmitted from the lock 3 to the key 2 in the transmission direction 4 ', so that the laser radiation emitted by the laser diode 13 is modulated accordingly for energy transmission 12 .

Further, in the lock 3, a receiving circuit 27, which 'is in communication, for the key 2 on the lock 3 in the transmission direction 4' having the light emitting diode 15 'are arranged to be transmitted code as shown in FIG. 7 can be seen. The receiving circuit 27 contains an impedance converter 28 for stabilizing the voltage output by the light-emitting diode 15 '. Since the light-emitting diode 15 'emits a relatively low voltage, the impedance converter 28 is followed by an amplification circuit 29 . The amplified voltage is then fed to a comparator 30 for level adjustment and then to the lock electronics 26 for further processing.

The electrical circuit for operating the key 2 is shown in more detail in FIG. 8 as a basic block diagram. In the key 2 there is a voltage stabilization circuit 31 for stabilizing the voltage emitted by the solar cell 14 , which serves for the voltage supply for the operation of the key 2 located in the lock 3 . In the key 2 there is also a demodulation circuit 32 for filtering out and amplifying the code transmitted in the transmission direction 4 ′ from the voltage emitted by the solar cell 14 . This code is then fed to key electronics 33 for further processing. With the key electronics 33 , the circuits for generating and decoding the code 4 u. Like. Contains, in turn, the light emitting diode 15 is connected, which emits the code in the transmission direction 4 ''. It is advisable to arrange the voltage stabilization circuit 31 and the demodulation circuit 32 on the circuit board 21 visible in FIG. 5.

The invention is not based on that described and illustrated Embodiment limited. Rather, it includes everyone professional training within the scope of the inventive concept. So the locking system cannot only be used as an ignition lock system find, but is also suitable for a Door locking system on both a motor vehicle and one Real estate.  

Reference list

1

Locking system

2nd

key

3rd

Lock

4th

Code (between key and lock) / code transmission

4th

',

4th

'' Direction of transmission (for code) / code transmission

5

Code (between key and receiving device)

6

Action (can be triggered by a lock)

7

Actuator

8th

Interior mirror

9

Receiving device

10th

Control unit

11

car door

12th

optical energy transfer

13

Laser diode

14

Solar cell

15

,

15

'(green) LED

16

rotor

17th

admission

18th

Insertion opening

19th

bracket

20th

Front (from key)

21

Circuit board

22

Part of the key (can be inserted into the holder)

23

flap

24th

Lock electronics

25th

Laser driver circuit

26

Modulation circuit

27

Receiving circuit

28

Impedance converter

29

Amplification circuit

30th

Comparator

31

Voltage stabilization circuit

32

Demodulation circuit

33

Key electronics

Claims (11)

1. Electronic locking system, in particular ignition lock system for a motor vehicle, with an electronic lock ( 3 ) and an electronic key ( 2 ), with means for the optical transmission of energy ( 12 ) from the lock ( 3 ) to the key ( 2 ), the The key ( 2 ) can be operated by means of the transmitted energy ( 12 ), and by means for the optical transmission of a code ( 4 ) between the lock ( 3 ) and the key ( 2 ), with at least one after positive evaluation of the transmitted code ( 4 ) Action ( 6 ) can be triggered in and / or by the lock ( 3 ), such as the release of functions, switching on the ignition, starting or the like of the motor vehicle, characterized in that the means for transmitting the code ( 4 ) can be operated with an optical frequency which in at least one transmission direction ( 4 ″) between the key ( 2 ) and the lock ( 3 ) is different from the optical frequency of the energy projection ( 12 ). 2. Electronic locking system according to claim 1, characterized in that the means for energy transfer ( 12 ) from the lock ( 3 ) to the key ( 2 ) work by means of laser radiation, in particular by means of infrared laser radiation, preferably the means for energy transfer ( 12 ) a laser diode ( 13 ) located in the lock ( 3 ), in particular a GaAlAs laser diode, and a solar cell ( 14 ) located in the key ( 2 ). 3. Electronic locking system according to claim 1 or 2, characterized in that the means for transmitting the code ( 4 ) in the transmission direction ( 4 '') from the key ( 2 ) to the lock ( 3 ) with a higher frequency than the means for Energy transmission ( 12 ), in particular working with at least green optical radiation, that preferably the means for transmitting the code ( 4 '') from the key ( 2 ) to the lock ( 3 ) from electro-optical converter elements, such as light-emitting diodes, photo transistors or the like, consist in particular of green light-emitting diodes ( 15 , 15 '), and that further preferably the means for transmitting the code ( 4 ) in the transmission direction ( 4 ') from the lock ( 3 ) to the key ( 2 ) from the means for energy transmission ( 12 ) exist, in particular the code ( 4 ') of the laser radiation to be transmitted being modulated. 4. Electronic locking system according to claim 1, 2 or 3, characterized in that the lock ( 3 ) has in particular in the manner of a rotor ( 16 ) formed receptacle ( 17 ) with an insertion opening ( 18 ) for the electronic key ( 2 ) that preferably the means for energy transmission ( 12 ) and code transmission ( 4 ) assigned to the lock ( 3 ) are arranged on the side of the receptacle ( 17 ) opposite the insertion opening ( 18 ), and that the key ( 2 ) assigned means for energy transmission ( 12 ) and code transmission ( 4 ) are arranged on the front ( 20 ) of the part ( 22 ) of the key ( 2 ) which can be inserted into the receptacle ( 17 ), such that the means for energy transmission ( 12 ) and code transmission ( 4 ) in the key ( 2 ) and in the lock ( 3 ) face each other. 5. Electronic locking system according to one of claims 1 to 4, characterized in that the means for energy transmission ( 12 ) and code transmission ( 4 ) in the lock ( 3 ), in particular the laser diode ( 13 ) and the green light-emitting diode ( 15th '), are fastened to a holder ( 19 ), the holder ( 19 ) preferably being designed in the manner of a stator, further preferably projecting into the rotor ( 16 ) and even more preferably serving as a heat sink for the laser diode ( 13 ). 6. Electronic locking system according to one of claims 1 to 5, characterized in that on the lock ( 3 ) a device for closing the insertion opening ( 18 ) in the receptacle ( 17 ) with the key ( 2 ) removed is arranged, preferably the device flaps ( 23 ) which can be moved laterally when the key ( 2 ) is inserted under spring load and can be automatically reset when the key ( 2 ) is removed due to the spring force. 7. Electronic locking system according to one of claims 1 to 6, characterized in that the means for energy transmission ( 12 ) and code transmission ( 4 ) in the key ( 2 ), in particular the solar cell ( 14 ) and the green light-emitting diode ( 15 ), are attached to a printed circuit board ( 21 ) which is preferably arranged inside the part ( 22 ) of the key ( 2 ) which can be inserted into the receptacle ( 17 ). 8. Electronic locking system according to one of claims 1 to 7, characterized in that in the lock ( 3 ) a laser driver circuit ( 25 ) for the laser diode ( 13 ) is arranged, that preferably the laser driver circuit ( 25 ) contains a switching voltage regulator, whose output voltage is fed to a modulation circuit ( 26 ), and that further preferably a power semiconductor, such as a MOS-FET or the like, is arranged in the modulation circuit ( 26 ), which corresponds to that of the lock ( 3 ) the key ( 2 ) to be transmitted code ( 4 ') modulates the current supplied to the laser diode ( 13 ). 9. Electronic locking system according to one of claims 1 to 8, characterized in that in the key ( 2 ) a voltage stabilization circuit ( 31 ) for stabilizing the voltage output by the solar cell ( 14 ) for the operation of the key ( 2 ) is arranged, and that there is preferably in the key ( 2 ) a demodulation circuit ( 32 ) for filtering out and amplifying the code ( 4 ') from the voltage output by the solar cell ( 14 ). 10. Electronic locking system according to one of claims 1 to 9, characterized in that in the lock ( 3 ) a receiving circuit ( 27 ) with a light-emitting diode ( 15 ') for the code ( 2 ) to be transmitted to the lock ( 3 ) ( 4 '') that the receiving circuit ( 27 ) preferably contains an impedance converter ( 28 ) for stabilizing the voltage emitted by the light-emitting diode ( 15 '), that the impedance converter ( 28 ) also preferably has an amplification circuit ( 29 ) for the emitted voltage is connected downstream, and that even more preferably the amplified voltage is fed to a comparator ( 30 ) for level adjustment. 11. Electronic locking system according to one of claims 1 to 10, characterized in that the solar cell ( 14 ) has a size such that the radiation emitted by the laser diode ( 13 ) in all rotor positions of the receptacle ( 17 ) from the surface of the solar cell ( 14 ) is covered.