PL171282B1 - Electronic locking system - Google Patents

Abstract

An electronic locking arrangement comprising a lock unit (17) and a key unit (19) is proposed. Each of the units has a control circuit (35, 41) and a transmitting and receiving circuit (33, 47, 39, 43) which transmit information signals inductively via coupling coils (21, 23) to the control circuit (35, 41) of the other particular unit. The transmitting and receiving circuit of the lock unit (17) has an amplitude modulator (33) and a frequency demodulator (47) for the transmission of the information signals, whilst the transmitting and receiving circuit of the key unit (19) comprises a frequency modulator (43) and an amplitude demodulator (39). In dependence on the information signals transmitted between the units (17, 19), the control circuit (35) of the lock unit (17) generates a control signal representing the locking state. The transmission of the information signals takes place via a single pair of coupling coils (21, 23) utilised in both transmission directions. The amplitude modulator (33) modulates the high-frequency signal of a free-running high-frequency oscillator (27), the frequency-determining circuit of which comprises the coupling coil (21) of the lock unit, whilst the amplitude demodulator (39) is connected to the coupling coil (23) of the key unit (19). The frequency modulator (43) is likewise connected to the coupling coil (23) of the key unit (19) and detunes the frequency-determining circuit of the high-frequency oscillator (27) in dependence on the information signal to be transmitted. The frequency demodulator (47) is also coupled to the high-frequency oscillator (27). The locking arrangement permits high locking security, along with a high data transmission rate, at a comparatively low outlay in terms of structural parts. <IMAGE>

Description

The present invention relates to an electronic circuit for reciprocally transmitting information signals between a lock unit and a key unit in locking systems.

Hitherto known systems of this type include a lock assembly and a key assembly, each of which uses a control circuit, transmission and reception circuits, which transmit the meter via coupled coils, information signals of a large control circuit of the cooperating assembly. The sending and office systems of the first unit, especially the lock unit, must have the amplitude and frequency modulator for transmitting information signals. The sending and office systems of the second unit, especially the key unit, contain the frequency and amplitude modulus, and the key unit control circuit, depending on the information signals transmitted between the units, produces a control signal representing the closing conditions.

From patent entry No. DE-A-P5 17 858 an electronic locking system is known with a mechanical lock including a lock assembly and a key assembly using a flat key. Each of these assemblies comprises a trauma control circuit, sending and thrust circuits which are inductively coupled to the transmission of information signals through the coupling coils. The large lock generator frequently transmits rubble energy for the key assembly through the first of the coupled coils. The locking information stored in the memory of the key unit is conveyed to the lock unit by a second coupled pair of coils, by modulating the frequency of the signal generated by the key unit large frequency generator, and purifying with the locking data resolved in the memory of the lock unit to produce one with control signals related to the position of the lock. In order to be able to implement π ^ οζοι ^ closure placed in the memory of the lock assembly, the signal carried by the first pair of coupled coils can be amplitude modulated by the genesis of the lock assembly. The key assembly comprises, for programming purposes, an amplitude modulation which disconnects the closing information. In order to increase the certainty of the closing it is required that the closing information signals are transmitted in both directions between the lock assembly and the key assembly. The flow of information in both directions should not, however, influence each other. In order to limit as much as possible the mutual influence of infusions transmitted between the lock assembly and the key assembly, as is known from the patent entry

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DE-A-32 44 566, the transfer times should be mutually accurate and at the same time the axes of the coupled coil pairs should be set at an angle of 90 degrees to each other.

EP-B-28 78 86 discloses a transmission signal frequency selector with which locking information is transferred from the key unit to the lock unit, with which operating energy is transmitted through the first pair of coupled coils from the lock unit to the key unit. Filters ensure decoupling of the received signals.

EP-A-28 87.91 discloses a system for transmitting information signals in both directions between the lock unit and the key unit through a single pair of coupled coils in high frequency modulation, in which synchronously controlled switches are used in both the key unit and the lock unit. that connect the coupling-coil exchange method to a modulator or demodulator.

Moreover, from DE-C-34 02 737 a system for transmitting information signals between the lock unit and the key unit via a single pair of coupled coils is known. The coupled coil of the lock unit is connected to the output of the high frequency generator and the coupled coil of the key assembly is associated with a damping circuit controlled by the control circuit. Depending on the amount of damping of the coupled coil of the key assembly, the amplitude of the high frequency current in the coupled coil of the lock assembly inductively coupled to the coupled coil of the key assembly varies. Amplitude variations represent key assembly closing information. For the synchronization of the lock assembly with the key assembly, the high frequency generator additionally produces a periodic synchronization signal transmitted as a phase shift of the high frequency generator.

The known electronic locking systems shown and discussed are either of a more complex design, i.e. they require either more pairs of coupled coils or high frequency generators on both the lock side and the key side resulting in increased current consumption or the data rate being relatively low, which reduces the security of the closure or increases the operating time of the closure system.

An electronic system according to the invention for mutually transmitting information signals between a lock assembly and a key assembly in locking systems includes a key assembly and a lock assembly including control circuits and amplitude and frequency modulators. The transmission of the information signal is accomplished by an electromagnetic resonant system that includes a self-excited high frequency generator, a lock assembly coupling coil connected to the high frequency generator, and a key assembly coupling coil inductively coupled to the lock assembly coupling coil. A system of this type is characterized in that the lock unit amplitude modulator is connected with its input to the control circuit of the lock unit and with its input to a high frequency signal generator with an amplitude regulated by the control circuit. The input of the key assembly modulation circuit is connected to the key assembly control circuit and its output to a damping controlled element which is connected to the key assembly coupling coil. In addition, the lock unit frequency modulator is connected through its input, via a pulse shaping circuit, to the high frequency generator and to the output of the lock unit control circuit. Connected to the key unit coupling coil is the input of the key unit amplitude modulator, the output of which is connected to the key unit control circuit.

It is preferable that a high frequency generator is connected to the output of the amplitude modulator of the lock assembly via a power cord clamp to regulate the amount of power applied. The high frequency generator and the lock assembly coupling coil are preferably components of the first construction unit, and the amplitude modulator and the lock assembly control circuit are components of the second construction unit which also includes the frequency modulator of the lock assembly as a component. The input of the frequency modulator is connected to the power cable terminal of the high frequency generator.

It is preferable that the modulation circuit of the key assembly is made in the form of a pulse width modulator.

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The high-frequency generator power line terminal is preferably connected to an impedance to which the frequency modulator of the lock assembly is also connected. The high-frequency generator is preferably designed as a capacitive-coupled three-point generator. Said impedance is preferably made as an inductance and the input of the frequency modulator is connected to this impedance via a pulse shaping circuit, preferably in the form of a Schmitt trigger circuit.

It is preferred that the power lead terminal of the self-excited high frequency generator is connected to the output of the amplitude modulator, which includes a network of controlled resistance resistors connected to a switching element whose actuating terminal is connected to the input of the amplitude modulator.

It is preferred that the coupling coil of the key assembly is part of the resonant circuit. A diode voltage multiplier circuit is connected to the resonant circuit for generating the supply voltage. Connected to the resonant circuit is the output of the modulation circuit of the key assembly, which modulation circuit comprises a damping resistive network with a controlled resistance value connected to a switching element whose actuating terminal is connected to an input of the modulation circuit.

It is further preferred that the lock assembly includes an electromagnetically actuated locking member connected to the control circuit of the lock assembly via an unlock signal wire. The locking element is mounted in the first structural unit, which is a lock cylinder that is mechanically actuated by means of a flat key. The wrench assembly is a component of the flat wrench, and the wrench assembly's coupling coil is connected to the input of a rectifier circuit whose output is connected to the wrench assembly power inputs.

The connection of a coupled key-side coil to the frequency setting circuit of the self-excited lock-side generator enables the system of the invention to transmit modulated amplitude information from the lock assembly to the key assembly and transmit frequency modulated information from the key assembly to the lock assembly. The closure system according to the invention requires only one pair of coupled coils and furthermore does not require any own frequency generator on the key side to transmit information.

The manufacturing costs of the electronic closing system according to the invention are relatively low, and the system provides a high security of closing with a short response time.

A closure of this kind requires a single high frequency generator and one pair of coupled coils d ^ i to carry information signals in both directions. The information transfer rate is determined primarily by the frequency of the high frequency generator, which may be appropriately selected to obtain a relatively high data transfer rate, e.g. 2 MHz or more. Since the key assembly does not require its own high frequency generator, the current draw of the key assembly is small. The required operating current is obtained solely from the RF signal carried by the coupled coils. The information is transferred simultaneously or sequentially in both transmission directions, with the simultaneous transmission connected to the frequency modulator in series with an amplitude limiting circuit which limits the effect of amplitude changes caused by the amplitude modulator on the frequency modulator. Any common frequency modulation circuit is suitable as a frequency modulator, and pulse width modulators which convert the transmitted high frequency signals into pulsed pulse width modulated signals are particularly suitable.

The locking system includes a mechanically lockable lock cylinder into which a flat key belonging to the key assembly fits. Common lock drums have standardized dimensions so that the lock assembly components take up relatively little space. Preferably, the output amplitude of the high-frequency generator, depending on the amplitude of the operating voltage or the operating current of the generator, is variable and the amplitude modulator is

171 282 modulates the amplitude of the operating voltage or operating current. The oscillator and the coupled coil form one construction unit, and the amplitude modulator and the control circuit form a second construction unit, separate from the first construction unit. In this way, only one component of the lock assembly is used in the locking cylinder, while the other component of the assembly may conveniently be separated by the control circuit from the locking cylinder, for example inside the lock box, but also separate from the lock box. Since the amplitude modulator modulates the operating voltage or the operating current of the generator, it is not necessary to connect additional data cables to the generator in addition to the necessary voltage supply lines. This reduces the number of connecting lines between the closure cylinder and external system components.

The high frequency generator is preferably a three point generator, for example a Colpitts generator. Generators of this type have the advantage of having a very simple structure and the operating current of the generator's amplification element, such as a transistor, flows through the coupled coils. Moreover, in such generators the operating voltage can be varied within very wide limits. Such a generator is particularly well suited for changing very low operating voltages. The diode voltage multiplier system used allows to increase the operating voltage.

The key assembly frequency modulator is used as a resistance damping circuit connected to a resonant circuit whose resistance is gradually adjusted by the key assembly control circuit.

The high certainty of closing in combination with greater operational reliability can be increased if the key unit control circuit periodically sends activation signals upon receipt of which the key unit sends a response signal, and if the lock unit control circuit, upon receiving the response signals, sends closing data upon receipt of which the key unit sends latch data to the lock assembly.

To be sure of the closure, the key unit sends a data block that contains the previously accepted closing data and the closing data from the key unit. The lock unit control circuit uses the locking data transmitted in the data block to generate the control signals. For example, the key set may transmit data contained in its controller, but may also process the updated data received from the key set according to a specific algorithm. Also, the locking data previously received by the lock unit and the locking data of a specific key are transferred back and used by the lock unit, which ensures a very high security of the closing.

The solution according to the invention is explained in an embodiment in the drawing, in which Fig. 1 shows a side view of the electronic closing drum, Fig. 2 - front view of the closing drum, Fig. 3 - side view of the electronic flat key, matching the closing drum, Fig. 4 is a block diagram of a preferred example of an electronic locking system arranged in the locking cylinder and flat key of Figures 1-3, and Fig. 5 is a diagram explaining the construction of the locking system.

The system according to the invention for transmitting information signals comprises a lock assembly 17 and a key assembly 19. Lock assembly 17 preferably comprises two separate construction units 1 and 31. The first structural unit is a locking cylinder 1.

As shown in Figures 1 and 2, the locking cylinder 1 comprises a profiled housing with a hollow core 3 arranged therein, connected to the locking cylinder 1 by several pairs of holding pins 5. With the flat key 7 (Figure 3) of the pair of holding pins 5 removed. lock the core 3 in the profiled housing of the locking cylinder 1. After inserting the blade 9 of the key into the channel of the key 11 of the core 3, a flat key 7 fitted to the locking cylinder 1 moves the retaining pair of pins 5 towards the housing of the cylinder core so that it can be turned.

In addition, an electromagnetically controlled locking element 13 is provided in the profiled housing of the closing cylinder 1 for the mechanical holding pairs of pins 5, which, in its normal state, is in the normal state, e.g.

171 282 of the locking pin 15 locks the core 3 but is released for the duration of the excitation pulse. The locking element 13 is controlled by the lock assembly 17 (FIG. 4) depending on the locking information sent by the key assembly 19 by means of a flat key 7 inserted in the channel of the key 11 through. in a single pair of coupling coils 2123. The key assembly 19 is, as shown in Figure 3, received in a key holder 25 7. The engagement coil 21 of the lock assembly 17 is secured to the housing of the profile lock cylinder 1, e.g. the entry of the key channel 11, and the engagement coil 23 of the key assembly 19 is provided on the blade of the key 9.

The coupling coil 21 of the lock assembly 17 is part of a fixed frequency circuit of, for example, a vibrating LC system, unloaded and therefore not frequency stabilized by a vibrating quartz or similar high frequency generator system 27, the supply voltage of which is supplied via a line 29 from a remote cylinder 1. of the second construction unit 31 of the lock assembly 17. The generator 27 is parameterized so that the amplitude of the signal of the coupling coil 21 varies depending on the supply voltage supplied from the conductor 29. The supply voltage is supplied by an amplitude modulator 33 through which the amplitude produced by the coil is modulated high frequency magnetic field coupler 21 in response to the information data provided by the control circuit 35.

A high frequency generator 27 is connected to the output of the amplitude modulator 33 via the feed line terminal 63 (FIG. 5), the amplitude modulator 33 changing the magnitude of the power supply to the self-excited high frequency generator 27.

With the key 7 inserted, the coupling coil 23 is inductively coupled by a high-frequency magnetic field to the coupling coil 21. Connected via the input circuit 37 to the coupling coil 23, the amplitude modulator 39 separates the information data from the carrier signal of the high frequency generator 27 and transmits it to the control circuit 41 of the key assembly. The frequency of the high-frequency signals produced by the resonant circuit varies according to the signal generated by the control circuit 41 of the key assembly 19.

The control circuit 41 sends information data to the lock assembly 17. The information data is transmitted via modulation circuit 43 to an input circuit 37 connected to a coupling coil 23, the damping of which is regulated by a combined impedance. The coupling of the coil 23 to the fixed frequency circuit of the generator 27 allows the frequency modulation of the fixed frequency circuit by the modulation circuit 43, which causes the operating current to pulsate in the conductor 29 at the rate of frequency modulation. The construction unit 31 includes a frequency modulator 47 connected by a pulse shaping circuit 45 to a conductor 29, separating the frequency modulated information data from the carrier signal of the generator 27 and transmitting it to a control circuit 35 that processes it. The control circuit 35 compares the received closing data with the closing data transmitted from the key unit 19 and, in the event of a match, transmits a predetermined length pulse through the amplifier 49 and line 51 to the blocking element 13. The rectifier circuit 53 connected to input 37 generates the induced in the rectified AC voltage coupling coil 23 the operating voltage for the entire wrench assembly 19.

A frequency modulator 47 connected via an input to the high frequency generator 27 and to the output of the control circuit 35 of the lock assembly 17, sends to the control circuit 35 of the lock assembly 17 a receive signal corresponding to the transmit signal generated by the control circuit 41 of the key assembly 19 depending on the frequency of the resonant circuit.

An input amplitude modulator 39 connected to the coupling coil 23 of the key unit 19 and its output to the control circuit 41 of the key unit 19 sends to the control circuit 41 of the key unit 19 a receive signal corresponding to the transmit signal sent by the control circuit 35 of the lock unit 17 depending on the frequency of the produced in the resonant circuit of the high frequency signal.

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As shown in Figures 1 and 2, the housing of the profile closure tumbler 1 is a single construction unit and comprises a connecting plate 55 on which only the generator 27 and the coupling coil 21 are mounted. The remaining elements of the lock assembly 17 are contained in the outer second construction unit 31, and they are connected with only a few conductors to the connecting plate 55.

The information data transferred between circuit circuits 17, 19 may include timing data as well as shutdown data. The carrier signal of generator 27 carries modulated pulses in both directions.

The coupling coil 21 creates a high frequency magnetic field by which the control circuit 35 periodically modulates the amplitude of the drive signal. The magnetic field present in the key channel 11 induces an alternating voltage in the coupling coil 23 from which the rectifier circuit 53 connected to the input circuit 37 generates a rectified operating voltage for the circuits of the key assembly 19. After receiving the excitation signal, the control circuit 41 sends a response signal such that the control circuit 41 replies for its part with the shutdown data. The control circuit 41 responds to the received closing data with a data block which, in addition to the received closing data of the key assembly, contains the generated closing data depending on the received closing data. The control circuit compares its own shutdown data returning from the data block to the initially sent data and excludes the key assembly data. If the data matches, an unlock pulse is generated.

Fig. 5 shows details of the arrangement of Fig. 4. The high-frequency generator 27 located in the housing of the profiled closing drum 1 is designed as a Colpitts generator, i.e. as a capacitive-coupled three-point generator. The coupling coil 21 is connected in parallel to two series capacitors 57.59 and forms together with these capacitors a resonant frequency setting resonant circuit of the generator 27, the resonant circuit connected to the collector of the transistor 61 operating in the emitter circuit. The resonant circuit node 63 distant from the collector of transistor 61 is connected to the base of the transistor via a coupling capacitor 65, thus forming a positive feedback circuit. The connecting point between the two capacitors 57, 59 is connected to the emitter of the transistor 61. Node 63 is also a power supply cable terminal for the operating voltage of the generator 27. Located between the power cable terminal 63 and the base, the connected resistor 67 defines the operating point of the transistor 61 with the resistor 69 connected to ground. emitter branch.

The amplitude modulator 3 3 comprises a resistor 71 connected between an operating voltage source 70 (the second pole of which is connected to ground) and a power supply terminal 63 of the generator 27, which is switched by an electronic switch 73 controlled by the control circuit 3. The resistor 71 has such parameters, so that the voltage at the power supply terminal 63 is sufficient for the operation of the generator 27. If the switch 73 bypasses the resistor 71, the operating voltage of the generator 27 will increase and the generator 27 will create a magnetic field stronger than when the switch 73 is open.

There is an impedance 75 between the emitter resistor 61 and the ground on, through which a pulsating operating current flows at the generator frequency 27. A Schmitt trigger stage 77 from the impulse forming circuit 45 forms a falling pulsating voltage into a pulse signal under the influence of the operating current flowing through the impadance 75, the instantaneous pulse rate of which corresponds to the instantaneous frequency of the generator 27. The pulse signal is supplied to the control circuit 35 by timing and to a frequency modulator 47, which in the illustrated embodiment is a phase shifter circuit (PPL circuit). The frequency modulator 47 produces, depending on the reference signal 79 produced, the frequency of which is equal to the frequency of the generator 27, a corresponding output deviation or variation of the oscillation of the frequency of the generator 27 supplied by the amplifier 81 to the control circuit 35.

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With the key 7 turned on, a capacitor 83 is connected in parallel with the coupling coil 21 to the coupling coil 21, which together with the coupling coil 23 forms a resonant circuit with the frequency of the generator 27. A diode voltage multiplier circuit 85 is connected to the resonant circuit, here in the form of one of the diodes 87,89 and capacitors 91,93 forming a Delon voltage multiplier circuit. The resonant circuit provides a resonant overvoltage to the AC induced in the coupling coil 23, and the multiplier circuit 85 provides rectification of the AC voltage while doubling. The multiplier circuit 85 provides the operating voltage required to operate the electronics of the key assembly, in particular the control circuit 41.

The capacitors 91, 93 of the voltage multiplier circuit 85 also form a voltage divider to which the amplitude modulator 39 is connected. The amplitude modulator 39 preferably includes a rectifier circuit with an associated amplifier. The modulation circuit 43 includes a current surge suppression resistor 95 connected in series with an electronic switch 97 controlled by the control circuit 41 and disposed between the parallel resonant circuit of the coupling coil 23 and ground. When the switch is closed, the parallel resonant circuit is damped, which causes the reactive effect of the key's coupling coil 23 on the lock's coupling coil 21 to decrease, which leads to a change in the oscillation frequency of the generator 27. When the switch 97 is closed, the resonant circuit of the input circuit 37 of the key is taken from the alternating field The magnetic coupling coil 21 of the generator 27 has more energy than when the switch 97 is open. This energy can no longer be used by the oscillation circuit of the generator 27, which leads to an increase in the oscillation frequency of the generator 27. The resonant circuit of the input circuit 37 is here connected via a coupling resistor 99 to clock input of the control circuit 41 and thus ensures the synchronization of the control circuit 41. Both the control circuits 35 and 41 will hereby obtain the clock signal displaced from the oscillation frequency of the generator 27, which will allow the bit-coding of the information signals of the control circuit 35, 41 synchronously with frequently generator capacity. The data transfer does not undergo a fixed time division, so the duration of the data pulses determined by the control circuits 35, 41 depends on the fixed number of oscillation cycles of the generator. Therefore, no constant given frequency is needed for the key set.

The frequency modulation on the side of the second construction unit 31 of the lock may also be performed in a different manner. In particular, it is possible to obtain a frequency modulation directly dependent on the output signal of the pulse forming circuit 45 by means of a frequency measurement control circuit 35.

The principle of the closure system according to the invention will now be described. The control circuit 35 of lock unit 17 periodically sends the start signals. In response to the receive signal in accordance with the start transmit signal, key assembly 19 control circuit 41 outputs a response transmit signal. In addition, the control circuit 35 of lock unit 17 outputs coding data transmit signals in response to the receive signal according to the response transmit signal. In response to reception of the coding data transmit signals of the control circuit 35 of the lock assembly 17, the key assembly control circuit 41 transmits the coding data transmit signals. The coding data transmission signals of the control circuit 41 of the key unit 19 also include receive signals according to the coding data transmissions of the control circuit 35 of the lock unit 17. The control circuit 35 of the lock unit 17 compares the receive signals according to the data transmission signals of the control chain 41 of the key unit 19 with the commanded data. receive signals residing in the memory of the control circuit 35 of the lock assembly 17, and if they match, sends an unlock signal.

Claims (11)

Patent claims An electronic system for the mutual transmission of information signals between the lock assembly and the key assembly in locking systems, in which the key assembly and the lock assembly include control systems and amplitude and frequency modulators, and the transmission of the information signal is performed by an electromagnetic resonant circuit which comprises a self-excited high frequency generator, a lock unit coupling coil connected to the high frequency generator and a key unit coupling coil inductively coupled to the lock unit coupling coil, characterized in that the amplitude modulator (33) of the lock unit (17) is connected to the control circuit with its input (35) of the lock assembly (17) and the output to a high frequency signal generator (27) with an amplitude regulated by the control circuit (35), the input of the modulation circuit (43) of the key assembly (19) being connected to the control circuit (41). ) of the key assembly (19) and its exit from a damping controlled element which is connected to the coupling coil (23) of the key unit (19), and furthermore the frequency modulator (47) of the lock unit (17) is connected via its input via the pulse forming circuit (45) to the generator (27) and with the output of the control circuit (35) of the lock assembly (17), the coupling coil (23) of the key assembly (19) being connected to the input of the amplitude modulator (39) of the key assembly (19), the output of which is connected to the control circuit ( 41) of the spanner assembly (19). 2. The system according to claim A high frequency generator (27) is connected to the output of the amplitude modulator (33) of the lock assembly (17) via the feed line terminal (63) for controlling the amount of power supplied. 3. The system according to p. A device according to claim 1 or 2, characterized in that the high frequency generator (27) and the coupling coil (21) of the lock assembly (17) are components of the first construction unit (1), and the amplitude modulator (33) and the control circuit (35) of the lock assembly (17) ( 17) are components of a second construction unit (31) that also comprises a frequency modulator (47) of the lock assembly (17) as a component. 4. The system according to p. The method of claim 3, characterized in that the input of the frequency modulator (47) is connected to a power supply terminal of the high-frequency generator (27). 5. The system according to p. The method of claim 1, characterized in that the modulation circuit (43) of the key assembly (19) is made in the form of a pulse width modulator. 6. The system according to p. The power supply terminal of the high frequency generator (27) is connected to an impedance (75) to which the frequency modulator (47) of the lock assembly (17) is also connected to, as claimed in claim 4. 7. The system according to p. The method of claim 6, characterized in that the high-frequency generator (27) is preferably designed as a capacitive coupled three point generator. 8. The system according to p. The method of claim 6, characterized in that the impedance (75) is preferably made as an inductance and the input of the frequency modulator (47) is connected to the impedance (75) via a pulse shaping circuit (45), preferably in the form of a Schmitt trigger (77). The system according to p. The method of claim 6, characterized in that the power supply terminal of the self-excited high-frequency generator (27) is connected to the output of the amplitude modulator (33) which comprises a network of resistors (71) with a controlled resistance value connected to a switching element (73), the actuating terminal of which is connected to to the input of the amplitude modulator (33). 171 282 10. The system according to p. The method as claimed in claim 1, characterized in that the coupling coil (23) of the key assembly (19) is a component of the displacement slide (SP, 8P) circuit. 11 kTIdiwk 11. PLlClkl isrocdkiic Oncn * ^ ^v VVUlUg, ZjUOUZj. 1 tn trn (, ^ iutnb ^ gr dzrrk * iv, ŁuaunCuuj ij ui ₉ up g \ V> ^ sp, z ^ ii raTAł ^ o-noAiiiarrA m Q1 \ UiO vuwuu ivz.vnuH.n. ' a circuit (85) of the input voltage multiplier du for generating the supply voltage is connected in it. 1S. Layout in castrc. 10 albu 11, characterized in that the cs c ubwudsm rscunansuwym (SP, 8P) zapąccuns is the output of the mudzlacyjnsgu (4P) csspułz klzcca (19), which here the muffling circuit (4P) contains a damping recurrence network (95) at a controlled resistance value, connected with a switching element (97) with an actuating clip connected to the large muffler input (4P) 1P. The system according to p. A device as claimed in claim 1, characterized in that the lock assembly (17) comprises an electromagnetically actuated bluing device (1P) connected to the control circuit (P5) to the lock assembly (17) via a tamper signal line (51). 14. The system according to p. 1P, characterized in that the camunting element (1P) is fitted in the first functional unit (1) which is fitted with a locking cylinder that is mechanically actuated by a pumocate of a flat key (7), the key assembly (19) and a component part of the flat key (7) and the coupling coil (SP) of the key assembly (19) is connected to the input of the actuator circuit (5P), the output of which is connected to the power inputs of the key assembly (19).