NL8204801A - DEVICE FOR IDENTIFICATION OF INFORMATION, IN PARTICULAR AN ELECTRONIC LOCK KEY COMBINATION. - Google Patents

Description

703974

Title: Device for identification of information, in particular an electronic lock-key combination.

The invention relates to a device for identifying information. Such an information-identifying device is known from DOS 2657182 and comprises a first carrier unit (key part), the identification taking place by means of reading means forming part of a second carrier unit (lock part), the relevant information in a first information carrier located in the first carrier unit, in encoded form, said first carrier unit additionally comprising a receiving unit and a signal generator which can be influenced by the first information carrier 10, and the second carrier unit also comprising a receiving unit, as well as a processing circuit containing a second data carrier, as well as connected to an energy source, which can be coupled to the receiving unit of the first carrier unit such that energy transfer takes place, in order to transfer energy to activate parts of the first carrier unit, as well as the first inf control medium, such that the signal generator produces an information signal on which the information of the first information carrier is grafted, which information signal is received by the receiving unit of the second carrier unit and, if necessary, is compared with reference after conversion in the processing chain information from the second information carrier, wherein the processing circuit produces a characteristic output signal when a desired relationship exists between the first and second information.

An apparatus of the type described above is essentially characterized in that the receiving unit located in the first carrier unit comprises an energy processing stage which controls the first information carrier only when the received energy has a level greater than a lower limit value; The first and second carrier units include components to complete an electronic signal generator; the electronic components of the first carrier unit form frequency and / or amplitude determining circuit portions of the signal generator; 8204801 * * - 2 - the first carrier unit is provided with an oscillator at the output of which an impedance (coil) is located and the second carrier unit has a second impedance (coil) which can be coupled to the first impedance; and 5 the impedances (coils) contain ferrite parts, as well as being designed as ferrite antennas.

With such a known identification device in the form of a lock-key combination, the following problems exist with regard to the lock and key part: it must be possible to recognize a signal graft on the key side, on the lock side; the signal side on the key side must take place at precisely predetermined times, so that the lock side can only concentrate on these times, this lock side being synchronized with the signal appearance times at the signal recognition times; and encrypted key side signal grafting is required.

The invention with which it is intended to provide a solution for these problems is essentially characterized in that an inductively coupled synchronizing switch is realized and applied, wherein means are provided which have a more or less complete short circuit of the coil and an energy inoculation. to the signal of the coil, so that at times determined by a coincidence of counting results, both on the side of the key coil and on the side of the lock coil, there is an altered signal course.

An essential feature is that the short-circuit of the coil located on the key side takes place via a diode, which gives the advantage that, depending on the connection sentence of the diode, half a wave, for example the positive one, is not short-circuited, however is available for a pulse count, ensuring that the key-side switch is closed at exactly the time given by signal generation on the lock-side coil.

A further essential element of the lock-key combination according to 8204801 ♦ * - 3 - the invention can be seen from the fact that an electronic circuit is present on the key side, which samples and counts the half waves transmitted through said diode, whereby in this electronic circuit encoding is incorporated, thereby determining at which times the switch 5 shorting the key side coil becomes operative.

In further explanation of the invention, some embodiments thereof will be described below with reference to Figures 1 to 7, in which Figures 1 and 2 show diagrams of inductively coupled synchronizing switches; Figures 3 and 4 show diagrams of lock key chain devices of which the synchronizing switches are part and which are completed by the aforementioned electronic components; Figures 5 and 6 show signal waveforms; and Figure 7 shows a schematic of a chain device for grafting energy.

In the circuit arrangement shown in Fig. 1, a periodic signal is supplied to the coil Li by means of a generator G via a resistor R1. The components combined in this chain arrangement, and the aforementioned components, belong to the lock side with regard to their application in an electronic lock-key combination. A spool L2 located on the key side is coupled to the spool L1 located on the lock side in such a way that corresponding signals are shifted in phase across the two coils.

When the coil L2 is now short-circuited via the switch S2, not only does a changed signal course occur on the side of the coil L2, but such a short-circuit also manifests itself at the coil L1 in the point S1. The respective signal waveforms are shown in the drawings accompanying Figure 1.

The principle described above is illustrative of an inductively coupled switch.

Another type of such a switch arises when a change in coupling properties is introduced between the coils L1 and l2, in that the coils are moved away from each other, respectively, because a corresponding material M is connected between the coils 8204801 * - 4 - brought. In this way, the function of the switch S2 could be initiated or aborted. The switch would thus depend on the torque properties. It would then be an inductive torque switch.

As can be seen from the signal waveforms in Fig. 1, the signal disappears during the time in which a short circuit is formed by the switch S2. If it is somehow successful to short-circuit the signal at the switch S2 such that simultaneously a count of the signal across S2 is not interrupted, it is possible to synchronize the relevant signals with each other. More in particular, it is possible to close the switch S2 located on the side of the coil L2 just after the signal S1 has appeared again on the side of the coil Li a number of times. When the coil L2, as shown in Fig. 2, is short-circuited via a diode Dl 15, this object can be achieved. In this case, for example, the positive half waves of the signal are not shorted, so that they are available for counting. When the positive signal waves on the side of the coil L2 are counted, the switch S2 can be closed exactly at a time given by the signal generation on the side 20 of the coil L1.

Thus, when the frequency on the signal generator side changes, the frequency on the switch side also changes, but the count of the positive half waves remains unchanged, so that still exactly on the equal wave passage, however, with another time difference between the switching events are switched.

The principle of the solution to the problems outlined above has been illustrated by the chain device according to Figure 3, which shows how an electronic circuit E2 has been added to the chain device according to Figures 1 or 2. This electronic chain does service for sampling and counting, for example, the positive half waves of the key chain via the point S3. Encoding is incorporated in the electronic circuit E2 to determine when the switch S2 is short-circuited. Of the two signal wave forms, it is no longer that of the lock chain that is decisive, but that of the key chain. At a certain point in time (after n positive half waves 8204301 • "W · - 5 - waves of the signal have appeared) a short circuit is formed, which manifests itself in SI over a time interval Δt.

According to this principle, the keys-side signals can be detected and detected perfectly synchronized at S1.

Also added is the component E1 which is arranged to form a DC voltage signal from an AC signal. This component provides the energy supply on the key side. Here too, the advantage is that only half a wave is continuously cut off, so that no permanent disruption in the energy supply is noticeable.

The chain device shown in Fig. 3 can. be further improved in order to make it possible to use the signal in an even more pronounced manner as a carrier of information. In the circuit arrangement shown in Fig. 3, the signal from the signal generator is superimposed on the short-circuited signal, the aim now being to isolate this signal from the ground signal of the signal generator in an even more unambiguous manner.

There are essentially two ways of doing this. Namely, corresponding signal manipulations can be performed either in section 2 or in section 1. Any additional provision to be added to the appropriate section (here key section 2) is a problem. Any additional manipulations in this section that must be performed to improve signal transfer increase the number of components required, and thus the power consumption and volume. Additional provisions should thus only be arranged in that part which makes this possible on the basis of its spatial structure. However, the embodiments to be described in the following can essentially be applied to the part 1 as well as to the part 2.

The solution to be given here is based on the assumption that a second coil L3 is arranged in the part 1 separately from the coil L1 in such a way that the electromagnetic influence of the coil L2 on the coil L3 is negligible. If the coil L3 is then coupled in a suitable manner to the coil L1 in a chain-technical manner, with the ground signals developed thereon being completely equal, all deviations from this equality can be unambiguously recorded via a differential amplifier.

8204801 m% - 6 -

In fig. 4 the solution to this problem is sketched. In Fig. 5 the signals developed in points A, B and C are shown as they arise when the part 2 is not in the vicinity of the part 1. The self-inductors L1 and L3 are tuned via the resistors R1 and R3 in such a way that the signals developed thereover in points A and B are mutually shifted in phase. Due to the difference between the signals A and B, which are applied to the input of the operational amplifier 0P1, the signal C is produced at the output of this operational amplifier.

When the part 2 is now brought in the vicinity of the part 1, the total inductance as given by the self-inductances L1 and L2 which are now in close proximity to each other, changes the signal course A such that with correct dimensioning of the resistors R1 and R3, the signals A and B accurately cover each other, respectively, when the coils L1 and L3 are wound in opposite directions, have been phase shifted by 180 ° with respect to each other. Since the difference between the signals A and B applied to its input has become zero, the output of the operational amplifier will no longer be produced. The C-line will be identical with the O-line (have a constant value respectively). This changes when the switch S1 is closed.

The coil L2, which, when the switch is open, receives energy from the coil L1, which generates a corresponding voltage across the resistor R2, is short-circuited, causing the field to disappear, as a result of which the coil L1 is immediately affected, resulting in a signal variation such as that is indicated at the location indicated by t in Fig. 6. This switching change occurring in the section 2 does not affect the coil L3 located in the section 1 since it is far enough away from the coil L1.

The course of these events is illustrated in Fig. 6.

The two signal waveforms A and B of Fig. 5 are combined into one waveform in Fig. 6. Only at the location of t (the time when the

Cd switch Sl is closed) a short-lived difference arises between the two signals. As a result, the input signal of the operational amplifier which at its output reproduces the signal accordingly is amplified according to the course C-7. This signal represents such a clear representation of the change of state of the switch S1 that this signal can be further processed electronically without great difficulty.

The chains located in parts 1 and 2 can also be automatically tuned or adapted to each other if the resistors R1 and R3 are designed as voltage regulating resistors. In this case, the operational amplifier output signal is used to change one of the resistors to -10 so long that the output signal has reached a minimum value.

Instead of the measure of short-circuiting the key-side coil L2 by means of the switch S1, a synchronous switch can also be realized by introducing an additional load of the coil L2 by means of a via a The uncharged capacitor connected to said coil, however, it should be remembered that such a capacitive short circuit is not equivalent to the greatest possible load obtained as a result of closing a switch, and that the; known per se, exponentially decreasing operation of the capacitive short circuit, in connection with the realization of a synchronous switch, is not useful.

On the other hand, the supply of energy stored in a charged capacitor offers a further possibility of obtaining synchronism via coil-influencing. The capacitor is connected to the coil by means of a switch, the connection times of which can be determined by known measures for obtaining synchronism, for example by counting half waves.

Fig. 7 illustrates an exemplary embodiment illustrating the principle of a power supply based synchronous switch.

For this purpose, an additional capacitor is included in the key current circuit which can be connected via the short-circuit switch S2 to the self-inductance L2. The operation of the short-circuit switch S2 is controlled via the electronic circuit E3, so that at a suitable time the charge contained in the capacitor C1 is discharged via the self-inductance L2, so that 8204801-8 - due to the current caused thereby, an operation is applied to the lock coil LI. It is clear that in such a short circuit no energy is lost, but that the energy present in the capacitor C1 is supplied for a short time. Such an energy supply caused at time t ^ manifests itself in the resulting peak that arises in the waveform of Figure 7a.

8204 80 1

Claims (8)

1. Device for identifying information, in particular access control, which is assigned to a first carrier unit (key part), and with the aid of reading means forming part of a second carrier unit (lock part), the information in a first information carrier located in the first carrier unit is given in coded form, which first carrier unit is additionally provided with a receiving chain and a signal generator which can be influenced by the first information carrier, and the second carrier unit is also provided with a receiving chain, as well as with a second information carrier 10 processing circuit, as well as connected to an energy source which can be energetically coupled to the receiving circuit of the first carrier unit to transfer energy to activate components of the first carrier unit and to control the first information carrier such that the signal generator provides an information signal 15 whether the first data carrier contains, produces, information which signal is received by the receiving chain in the second carrier unit and, if necessary, is compared with reference information of the second data carrier after conversion in the processing chain, the processing chain producing a characteristic output signal when a desired relationship exists between first and second information, the first carrier unit comprising an oscillator at the output of which an impedance (coil) is applied, and the second carrier unit comprising a second coil which can be coupled to the first coil, characterized in that an inductive a coupled synchronizing switch is formed and used, means being provided which effect a more or less complete short-circuiting of the coil (L2) and an energy inoculation on the signal from the coil (L2), respectively. . so that at times determined by a coincidence of counting results, both on the side of the key coil (L2) and on the side of the lock coil (L1), a changed signal development occurs. Device according to claim 1, characterized in that the key side coil (L2) can be short-circuited via a diode (D1). 8204801 - 10 - Device according to claim 1 or 2, characterized in that an electronic circuit (E2) is arranged on the key side and is arranged to sample and count the half waves of the signal transmitted by the diode (D1), wherein a coding is incorporated in this electronic circuit, by means of which it is determined at which times the switch (S2) for shorting the coil (L2) located on the key side becomes active. Device according to claim 1, characterized in that for short-circuiting the coil (L2) it can be connected in parallel via a short-circuit switch to an uncharged capacitor (Cl). Device according to any one of the preceding claims 1-3, characterized in that the lock part comprises a further coil (L3) which is arranged spatially separated from the coil (L1) in such a way that the electromagnetic influence of the the key-side coil (L2) on the coil (L3) is negligible. Device according to claim 3, characterized in that the coil self-inductances (L1, L3) are tuned via variable resistors (R1, R3) such that no phase shift exists at comparable measuring points (A, B) between the signals present there ; and these phase-equal signals are applied to an operational amplifier (OP1) with differential inputs, the amplifier having an output signal having a waveform curve (C, FIG. 5). Device according to claims 5 or 6, characterized in that the resistors (R1, R3) are designed as voltage regulating resistors. Device according to claim 1, characterized in that a charge-containing capacitor (Cl) can be connected to the coil (L2) via a short-circuit switch (S3) that can be controlled by an electronic circuit (E3), (Fig. 7). 8204301