DE2629003B1 - Method and arrangement for displaying the presence of objects in a surveillance area, in particular for preventing shoplifters - Google Patents

Abstract

Marking elements which are attached to the objects are activated by two alternating magnetic fields generated in the surveillance area at frequencies which differ from the frequencies of the alternating fields. Radio-frequency interference is intended to be prevented without incurring the disadvantages of the beat principle. For this purpose, the frequencies of both alternating fields, which are alternately in-phase and in phase opposition, are maintained identical and synchronous in the surveillance time segment by means of interconnected sine-wave generators comprising counters (4, 4') activated by a pulse generator (2) and read-only memories (8, 8') with digital-analog converters (6, 6') connected downstream. The excitation frequency of one of the sine-wave generators (2, 4', 8') is delayed by one pulse of the pulse generator (2) in the phase shift time segment through periodic delay of its computational steps. For this purpose, a flip-flop (10) is connected via an inverter (12) to the counter (4') and a cycle counter (22) activated by the pulse generator (2) is provided by means of which signals are forwarded to the flip-flop (10) in such a way that the phase shift time segment begins with an O-signal and ends with an L-signal. <IMAGE>

Description

12. The arrangement according to claim 11, characterized in that the PE input of the period counter (22) via an inverter (18) with an input of a NAND gate (30) is connected, which input also applies the voltage + Ue is, and that the output of the period counter (22) via the transit time chain (16, 20, 28) is connected to the other input of the NAND gate (30), while the output of the NAND gate (30) is connected to the PE inputs of the counters (4, 4 ') 13. Arrangement according to one or more of Claims 8-12, characterized in that each digital-to-analog converter (6, 6 ') has a summing element consisting of an operational amplifier (32,32 '), to the sine voltage applied to the digital-to-analog converter (6,6') a voltage - UB is added, is connected downstream in such a way that the output voltage appears as a filtered and amplified sinusoidal voltage symmetrical to the 0 line The present invention relates to a method and an arrangement for display the presence of objects in a surveillance area, in particular for Prevention of shoplifting where there are two magnetic in the surveillance area Alternating fields generated and to be monitored Objects marking elements are attached, which as a result of the action of the two alternating fields at least generate a frequency that is different from the frequencies of the alternating fields and radiate.

A method and an arrangement of this type is from OS 21 60 041 known.

This known method and arrangement work with oscillating circles with open air coils to generate an alternating interrogation field in the monitored area, d. H. the exit of a shop, for example, the vibrations are excited by impulses, whereby radio interference voltages generally arise that over the long- and medium wave range. The goods to be monitored are marked with a marking element in the form of a soft magnetic, highly permeable and an additional parallel one hard magnetic strip provided. In the case of the not yet sold goods, both are Parts still unmagnetized; the marking element of the not yet sold goods therefore generated in the passage as a result of the constant field direction change of the interrogation alternating field narrow pulse signals, which a special detection coil detects natural oscillations stimulate. These are fed to evaluation electronics and finally solve one Alarm or similar off.

Because of the arbitrary position and direction of the marking elements when passing the passage it is desirable to check the field propagation of the interrogation alternating field constantly changing to cover all directions.

This field spread is on the one hand by the coil shape, on the other hand determined by the polarity of the currents in the two interrogation coils of the two coil circuits, one of the two sides has different poles one after the other Impulses excited.

It initially makes sense to avoid radio interference with two to work fixed sinusoidal voltages with a small frequency difference, e.g. B.

with 9.5 kHz and 9.6 kHz (beat principle). However, this creates various disadvantages: It is no longer possible to make a clear statement about the times at which the magnetic field strength passes through zero directly on the marking element because the spatial coordinates of the marking strip are not known. Well surrendered but by superimposing the earth field with the right and left coil fields Different times for the change at different points in the room the field direction, provided that the field generation on the coils with different phase positions or different frequencies. On the other hand, this marking element gives only if the two coil fields together have the same size and reverse direction like the earth field component in the direction of the marking strip have an impulse away. The point in time at which this impulse can be expected is due to the evaluation with regard to the distinction from external interference signals is very important.

Another disadvantage of the beat principle is the fact that the previously mentioned field constellation possibly during the passage through the monitored area does not occur at all or occurs so seldom that an alarm cannot be triggered.

Finally, because of the relatively small frequency difference the so-called drag effect between the two alternating fields occur, whereby an unintended temporary or full-time syn- chronization takes place. In this The signal pulses from the marking element would occur at such large time intervals come that under certain circumstances a very fast passage through the passage without triggering an alarm is made possible.

The object of the present invention is to overcome the disadvantages of the known Process and the arrangement to avoid and with simple means a process and to provide an arrangement in which the radio interference voltages are eliminated without that the disadvantages that arise when using the beat principle would occur.

According to the invention this is achieved by the characterizing features of Claim 1 and the subsequent further claims achieved.

The fact that during the monitoring period a completely synchronous and in-phase or anti-phase operation of the alternating fields is carried out, is an accurate time prediction for the arrival of the marker pulse possible, and more precisely, the greater the ratio of the alternating coil field strength to the earth field component is hereby can external disturbances from the actual Detection signals are largely differentiated. Furthermore, the time intervals so small between two evaluations that even passing the Passage is still detectable It is even possible to protect against false alarms to be increased by a multiple evaluation. On the other hand, by being quite uniform Phase shift of 1800 reached during the phase shift period, that only a very small bandwidth is required, so that by appropriate Filtering the radio interference mentioned above can be avoided.

Another benefit arises from using a digital one Sine generator with digital generation of the sine voltage and digital phase shift.

This makes it possible to change the frequency without the synchronous one To change the run or the timing. It is still possible to have several passes to be fully synchronized with each other in the case of several systems. The blanking signals for the evaluation can also be taken from the digital generator and no longer have to be readjusted on timers. A drag effect is impossible.

Further advantages and features result from the following, description given on the basis of the drawing.

As you can see, the arrangement consists of a digital one Sine generator for each alternating field.

The digital sine generator for the first alternating field is very simple and is largely similar to that on page 92 ff. in Elektronik 1976, issue 3 described digital sine wave generator with read-only memory. The values of the sine function are stored in a programmable or other read-only memory 8 and are switched on by means of the synchronous counter 4, which is fed by the pulse generator 2 is queried one after the other. The chronologically one after the other at the output of the read-only memory 8 standing digital values are converted with the aid of a digital-to-analog converter 6 and after a corresponding filtering result in the desired sinusoidal voltage. Determining for the frequency of the sinusoidal voltage are the number of selected angle steps, based on a full period, and the pulse generator frequency at the upstream Counter 4. For the number of steps a Chosen power of 2, namely 28 = 256 steps / period. It follows that all the resulting signals like number of periods in phase modulation and gate signals also as a power of 2 appear and thus without complicated decoding directly on counter 4 and on Counter 22 can be tapped as binary states. The number of steps was chosen so that that the maximum counter capacity is currently being fully used. This allows the There is no need for decoding for the zero reset. With 256 steps for one period, d. H. 360 ° results in an angular step of 1.406250. In the read-only memory 8 the values of the sine function for a full period, i.e. H. from 0-360 ".

However, the storage takes place in such a way that for the sine values the value +1 is added so that the sine values only change between 0 and +2 can. As a result, it is not necessary as in the case of the known digital one mentioned above Sine generator if the function values are only saved from 0 to 90 ", the Values of the sine function for the second, third and fourth quadrants by counting down, To form polarity reversal or repetition. Polarity reversal in particular places high frequency requirements to the operational amplifier to avoid distortions after the Avoid polarity reversal due to insufficient slew rate of the operational amplifier.

In order to use the full range of the digital-to-analog converter 6 To be able to use, the entire values of the sine function are stored in the read-only memory 8 are to be saved, converted proportionally. The digital-to-analog converter 6 is followed by an arrangement which, by simply adding the Voltage - UB the output voltage reaching the first alternating field as filtered and to obtain an amplified sinusoidal voltage symmetrical to the zero line. A polarity reversal circuit is not required here, so that in the area of the zero crossing of the sine function no distortion can occur. The arrangement consists of an operational amplifier 32, the non-inverting input of which is connected to ground, while the inverting input on the one hand via the resistor 38 to the digital-to-analog converter 6 is connected and on the other hand connected via the resistor 34 to the voltage - UB is. This ensures that the mean value of the current at the inverting input is again approximately at zero. The negative feedback resistor 36 increases the gain set and achieved by the capacitor 42 attenuation for high frequencies. Any residual DC voltage that may still be present is removed by a downstream high-pass filter finally eliminated The digital sine generator for the second alternating field exists just like that for the first alternating field from a synchronous counter 4 ', a Read-only memory 8 'and a digital-to-analog converter 6'. It is just the same mentioned arrangement is provided, which the output voltage of the digital-to-analog converter 6 'is transformed into a filtered and amplified sinusoidal voltage symmetrical to the zero line Here the arrangement consists of the operational amplifier 32 ', the resistors 34', 36 ', 38' and the capacitor 42 '.

To generate the periodic delay of the computing steps is a flip-flop 10 is provided. This is with its input via an inverter 12 connected to the output of the synchronous counter 4 '. being Q output is with your own K input and the Cl input of the upstream synchronous counter 4 'connected.

The uniform phase shift is caused by the fact that at Applying a zero signal to the S and R inputs of the flip-flop 10 shortly after reaching the maximum counter capacity a single pulse from the pulse generator of the total 256 is not counted.

The CO output takes over the coding of such a single step of the synchronous counter 4 'with the inverter 12. The zero signal at the S input is constant at. The zero signal at the R input is obtained by a period counter 22. This is connected on the one hand to the pulse generator 2 and on the other hand to its Cl input connected to the output of the synchronous counter 4 '. The period counter 22 is on a cycle time is set that corresponds to 210 = 1024 periods. The cycle time is divided into 2,384 periods for the synchronous time during which the excitation frequencies for the first alternating field and for the second alternating field are synchronous and either oscillate in phase or out of phase. This synchronous time is interrupted of the phase shift time, which has a number of periods of 128. The period counter is set up so that after 384 periods there is a signal at the NAND gate 24, this together with the counting pulse applied to the C1 input of the period counter 22 reaches the NAND gate 26 for the number of periods. The signal arrives from there via the inverter 14 to the R input of the flip-flop 10. This, as already mentioned, causes that during 128 periods each shortly after reaching the maximum Counter capacity of the synchronous counter 4 'a single pulse from the pulse generator 2 is not counted. This means that during this time there is a period of the sinusoidal voltage to the second alternating field does not take 256 steps, but 257 steps, i.e. h the The frequency of this sinusoidal voltage is 1/256 compared to the frequency of the first alternating field decreased. After 128 periods there is a phase shift of 1800. The period counter 22 is via the NAND gates 24, 26 and the inverter 14 an L signal is applied to the R input of the flip-flop 10, and it will now all pulses counted again for 384 periods. This game repeats itself continuously, so that in-phase synchronous operation for 384 periods of the two alternating fields occurs and after a phase shift interruption of 128 periods, the two alternating fields are operated in phase opposition, also during occurs over a period of 384 periods.

At a pulse frequency of the pulse generator 2 of 2.56 MHz and one The selected number of steps of 256 steps / period results in a frequency the generated sine voltage of 10 kHz. The frequency deviation is approx. 40 Hz during the Phase shift period, which lasts 12.8 ms, while the synchronous Takes 38ems and the total cycle time is 102.4 ms.

It should also be noted that when the function values are saved in the read-only memories 8, 8 'a shift of the address digits by 64 steps so that address 0 is the sine value for 900, address 64 is the Sine value is assigned for 1800 etc. This achieves that the phase shift pulse causes practically no noticeable distortion of the curve shape, since it is always in the Near the maximum of the function value of the sine function takes place.

The period counter 22 is according to a further feature of the invention used to generate a synchronization pulse when its full capacity is reached submit. For this purpose, a signal is sent from the CO output of the period counter 22 via the Runtime chain, consisting of inverters 16, 20 and NAND gates 28, to the NAND gate 30 passed, the other input of which via the resistor 40 to the voltage + UB is applied and is connected to ground via the capacitor 44 This input is also connected via the inverter 18 to the PE input of the period counter 22, while its output is connected to the PE inputs of the synchronous counters 4, 4 '. Whenever the full capacity of the period counter 22 is reached, a zero signal appears at the CO output, a synchronization pulse is generated with a slight delay on the synchronous counter 4,4 '. This Then there is no synchronization pulse Effect when everything runs synchronously, but when one is caused by a glitch If the shift has occurred, synchronization is compulsory without major curve distortion both oscillators brought about in the voltage maximum of the sinusoidal voltage. as well When the operating voltage is switched on, a directional signal is sent to all PE inputs generated to start all counters defined.

Through this synchronization and through the excitation by means of a single pulse generator 2 it is possible to have any number of exits of a shop to be provided with the monitoring device without running the risk of the Excitation frequencies diverge or, on the contrary, due to the so-called drag effect an unintentional, temporary or full-time synchronization occurs, whereby any surveillance to prevent shoplifting would be made impossible.

Claims (1)

Claims: 1. Method for indicating the presence of Objects in a surveillance area, especially to prevent shoplifting, in which two alternating magnetic fields are generated in the monitored area and transmitted to the objects to be monitored marking elements are attached, which as a result the action of the two alternating fields at least one to the frequencies of the alternating fields Generate and radiate different frequencies, I do not show that n e t that the alternating magnetic fields are coupled to one another that during at intervals of successive time periods during which an evaluation is carried out the presence of marking elements in the monitoring area is carried out, the frequencies of the two alternating fields are kept the same and synchronized and thereby alternately in phase or are out of phase and that between the monitoring periods the phase shift by 1800 each by a slight change in the excitation frequency one of the alternating fields is carried out 2. The method according to claim 1, characterized in that characterized that the duration of the monitoring period is a whole multiple, preferably at least three times the duration of the phase shift period, 3. The method according to claim 1 or 2, characterized in that the excitation the alternating fields are carried out by digital sine wave generators, their calculation steps triggered by a pulse generator, and that during the phase shift period the excitation frequency of one of the sine wave generators by periodically delaying the Calculation steps is reduced by one pulse from the pulse generator. 4. The method according to claim 3, characterized in that the delay 5. Procedure takes place in the area of the maximum and / or the minimum of the sine values according to claim 3 or 4, characterized in that the step number for the computing steps a power of the number two is chosen for a sine period. 6. The method according to claim 5, characterized in that the number of steps so high a power of the number two is chosen that the counter capacity is just full is exploited. 7. The method according to one or more of claims 3-6, characterized characterized in that the values of a full sine curve are stored in a read-only memory saved, whereby the values are initially positive by adding the value 1 and by multiplying the full range of a digital-to-analog converter be adjusted. 8. Arrangement for performing the method according to claims 1-7, characterized characterized in that the digital sine wave generator consists of one of a pulse generator (2) controlled counter (4 or 4 ') and a read-only memory (8 or 8'), in which the values of the sine function are stored and which by means of the counter (4 or 4 ') are queried one after the other, the fixed value memory cher (8 or 8 ') a digital-to-analog converter t6 or 6') is connected downstream that for generation the periodic delay of the computing steps a flip-flop (10) with its input is connected to the output of the counter (4 ') via an inverter (12), while its output with its own K input and the Cl input of the upstream counter (4 ') is connected, and that a period counter (22) is provided, which is also is controlled by the pulse generator (2) and at its Cl input with a at the output of the counter (4 ') applied counting pulse for the number of periods is, the signals for controlling the periodic delay of the computing steps from the period counter (22) to the R input of the flip-flop (10) in such a way that that when a 0 signal is present, the phase shift time segment begins and ends in the presence of an L signal. 9. Arrangement according to claim 8, characterized in that the counter (4,4 ', 22) are designed as synchronous counters. 10. Arrangement according to claim 8 or 9, characterized in that the outputs of the period counter (22), which alternate during 128 resp. Send a 0 or L signal to a NAND gate (24) for 256 periods are directed that the output of the NAND gate (24) and the counting pulse for the number of periods are passed to a further NAND gate (26) and that the output of the second NAND gate (26) via an inverter (14) to the R input of the flip-flop (10) is connected. 11. Arrangement according to one or more of claims 8-10, characterized characterized in that the PE inputs of the counter (4,4 ') with the output of the period counter (22) are connected via a transit time chain (16, 20, 28).