DE3820353A1 - Theft alarm device - Google Patents

Abstract

A theft alarm device uses labels (4-6) which are fitted to the goods to be protected against theft and transmit a signal in a radio-frequency magnetic field. To prevent the reception of interference signals which do not originate from the labels (4-6), the theft alarm device has a correlator (10) which correlates the signal arriving in the receiver with a reference signal which is derived from the transmitter by means of a frequency divider (11). <IMAGE>

Description

The invention relates to an anti-theft alarm device, Consists of a transmitter that prevents theft protective area with a high frequency magnetic field around there, one of the goods to be protected from theft attached plaque that receives the magnetic field and again a signal by means of a frequency divider det, as well as a receiver with optical / acoustic signal show for this signal.

Such anti-theft alarms For example, to prevent theft of goods steel used in shops and are generally known.

In the known anti-theft device is with the Were badly releasably attached to a plaque; this ent keeps you on e.g. 130 kHz tuned resonance circuit, which is at the input of a frequency divider. On whose The output is a resonance circuit with e.g. half the fre quenz coupled. A miniature battery takes care of that Power supply.

The door of the shop is surrounded by a wire loop of a transmitter - is fed - in our example with the frequency 130 kHz. When trying to steal the goods through the door, the badge gets into the magnetic field of the wire loop. The voltage thus coupled into the receiving circuit of the badge is converted by the frequency divider and emitted via the output circuit of the badge.

Also in the vicinity of the door is a receiving device for the signal emitted by the badge with the frequency 65 kHz in our example. The response of this receiver triggers an alarm signal.

This principle is e.g. in U.S. Patent 12 12 504 and DE patent 3 11 217. A device according to this ver driving is from TAG Radionics Ltd. in trade.

The signal from the theft alarm device of the pla chain is very weak because of the small dimensions of the Plaque only a small transmitting antenna and a small one Allow battery. The recipient is accordingly vulnerable ger therefore for interference signals from the environment, the one Can trigger a false alarm.

As a countermeasure, the receiving circuit must also do so be provided with a filter that the frequency of the pla chain let through, interference frequencies in the neighbor shaft of the signal frequency can be blocked. filter according to the usual resonance circuit principle are unsuitable, since they cannot be made narrow enough nen. A better one - also in the device from TAG Radionics used - solution is the application of the PHASE-LOCKED LOOP principle. A variable oscillator is so in its frequency adjusted so that it is in phase with the received signal. This control loop is relative immune to simultaneous frequency neighbors Interference signals.

The disadvantage of the PHASE-LOCKED-LOOP in this application lies in the fact that in the normal state, i.e. when there is none Badge is located near the receiving facility, the oscillator constantly scans for reception signal executes and in this state easily by one Interference signal is "captured". On such a disturbance the recipient then speaks the same way as on the plaques  signal and triggers a false alarm.

If you encounter this problem by narrowing the search term empire, one deals with the disadvantage that now more due to temperature drift or aging of the components also the useful signal of the badge outside the search area Reichs could lie and a theft no alarm would solve what was even more disadvantageous than a gel would be a false alarm.

The invention has for its object a theft so to train warning device of the type mentioned that your badge signal is reliably received, Interference signals remain as ineffective as possible.

This object is achieved in that to prevent the receipt of not from the badge the theft alarm device contains a correlator that arrives at the receiver fende signal with a from the transmitter by frequency division derived reference signal correlates, the off output signal of the correlator from the phase position of the emp catch signal is made independent in that several re correlator branches connected in parallel and with reference signals with different phases.

In the anti-theft alarm device according to the invention the interference-proof reception of the badge signal through ensure the application of the correlator principle. The principle known per se (e.g. in G. Ehrenstrasser: Stochastic signals and their application; Uni pockets 377, Hüthig-Verlag, Heidelberg, 1974) for the anti-theft alarm device so in an electronic Circuit implemented that the device interference signals largely suppressed. Furthermore, this circuit so simplified that they are set up with inexpensive components can be built.  

The anti-theft alarm device also contains measures for monitoring and display of any received external interference signals and for constant monitoring Checking the operating status. Faults are spoken of text issued to staff members, too has no knowledge of the function of the facility, make it clearly distinguishable from alarm signals.

To further clarify the invention, the following referring to the drawing. This shows in

Fig. 1 is a block diagram of the anti-theft alarm device of the invention,

Fig. 2 is a block diagram of a correlator of the theft warning system,

Fig. 3 shows the electronic circuit of a binary correlator formed as correlator,

Fig. 4 is a block diagram of the Störsignalüberwa monitoring the anti-theft device according to the invention.

Fig. 1 gives an overview of the function blocks of the anti-theft alarm device: 1 is the transmitter frequency generator, the signal of which is supplied via the narrow-band amplifier 2 to the transmission antenna 3 . This is usually designed as a wire coil of a few meters in diameter and consists of several turns. The magnetic field of the coil surrounds the area to be protected.

The plaque brought to the articles to be kept from theft consists of the receiving antenna 4 in the form of a coil filled with a ferrite core, the frequency divider 5 and the transmitting antenna 6 , also designed as a ferrite-filled coil.

The receiver part of the anti-theft device begins with the receiving antenna 7 , which in turn is designed as a ferrite coil. This is followed by a bandstop filter 8 , which keeps inevitable remnants of the transmitter frequency away from the receiver, and a selective amplifier 9 for the received signal.

The subsequent correlator 10 represents the most important part of the device according to the invention. In it, the received signal is compared with a reference signal which is derived from the transmitted signal generator 1 via the frequency divider 11 . In the event of frequency equality within a tolerance of a few Hertz, a DC voltage is present at the output of the correlator as an indicator that a signal from the badge or an interference signal that was initially indistinguishable from it was received. The circuit design of the correlator is described in more detail below.

The circuit part 12 checks whether the signal was the real signal of a badge or an interference signal generated outside the device. Furthermore, the operational readiness of the system is continuously monitored in this circuit unit with the aid of a test signal. The circuit part 13 finally contains the optical and acoustic signal generator for "fault" or "alarm". The message of a malfunction is output as a language text (eg "Attention malfunction!") In order not to confuse this message with an alarm signal. The fault and alarm evaluation according to the invention is described in more detail below.

The process of correlation - more precisely: the cross-correlation function KKF - of a signal f ( ω ₁ t) and a reference signal r ( ω ₂ t + d ) is described mathematically by

The operations contained in this formula carry out an arrangement according to FIG. 2, the elements of the arrangement being represented schematically as functional blocks. The first is the upper chain, which is then connected n times in parallel.

In the multiplier 14 , the received signal s ( ω ₁ t) with the reference signal r ( ω ₂ t + ϕ ) is multiplied with the correct sign. The product is averaged in the integrator 15 , a clock signal terminating the integration after the time T ab. The output signal of the integrator at this time is fed to the threshold detector 16 , which compares the signal with a predetermined fixed value and emits a signal at the output which characterizes the two states "threshold exceeded" and "not exceeded".

If the received signal has a different frequency than the reference signal, a signal with the difference frequency (beat) is present at the output of the multiplier 14 . If the time constant of the following integrator 15 is sufficiently large towards the beat frequency, the output level after the clock time is practically zero and the threshold value in 16 is not exceeded. So no signal is reported; in other words: the signal at the input of the chain is not the expected received signal.

If s ( ω t ) and r ( ω t ) signals of the same frequency and phase, there is a DC voltage at the output of the multiplier 14 , which the integrator 15 converts into a linear voltage that increases with time. The threshold value detector 16 then reports at time T by positive level at the output that the threshold has been exceeded.

The signal coming from the badge 4 , 5 , 6 now has the same frequency as the reference signal, but the phase can have any value, because different, not ideally matched filters are run through the entire path and also the frequency divider if necessary a rising or falling edge, which corresponds to a phase change of 180 degrees.

The circuit must therefore be expanded so that an Emp signal is reported with any phase angle. For this purpose, the chain of function blocks 14 , 15 , 16 is connected n times in parallel, the reference signal in each row having a different phase, since it is derived from the original signal via phase shifters 17 with a different phase rotation in each case. The phase angles are chosen so that the entire angular range of 360 degrees is covered evenly. There is now always a branch in which the phases of the received signal and the reference signal best match and at the output of which the receipt of the signal is reported. The smaller the phase steps between the branches, the better the condition of phase equality is approximated, but the greater the circuitry effort.

The outputs of all threshold value detectors 16 are linked via a logical OR function 18 . An H level can be taken from their output if at least one of the reception branches consisting of 14, 15 and 16 has responded, ie a valid signal has been received.

The following describes how the Effort can be reduced.

Fig. 3 shows a practical implementation of the Kor relators. The key point is the conversion of the analog input signals into square-wave signals by "hard" limitation. This takes place in the rectangular shaper stage 19 , at the output of which a binary signal (= digital signal) is present for further processing.

The multiplication of two binary signals is simplified to an EXCLUSIVE-OR operation which the circuit 20 carries out. The integration takes place in a known manner using an RC-connected operational amplifier 21 . The mutually connected Zener diodes 22 prevent the output voltage from 21 from saturating, which can lead to the oscillation of the operational amplifier. The controlled electronic switch 23 discharges the capacitor at the beginning of each clock period.

24 shows an example of the design of the following threshold value detector according to the invention: The signal to be tested is led simultaneously to two comparators, one to the non-inverting and one to the inverting input. Accordingly, there is one positive and one negative reference voltage at the differential inputs. The two outputs of the comparators are OR-linked (realized as "wired-OR" in the example). Circuit 24 is also known as a "window discriminator" circuit.

At the output of the integrator 21 there is a positive voltage in the range 180 to 360 degrees with negative phase voltage between the received signal and the reference signal. Since both the exceeding of a positive and a negative threshold are now reported by the subsequent threshold value detector 24 , it is no longer necessary to provide reference signals in the phase range 180 to 360 degrees, and thus the number of circuit chains 19-24 can be halved.

The n phase-shifted reference signals can also be easily generated by digital signal processing: the reference signal is carried out by means of a suitably selected clock frequency through a slide register 25 , from whose parallel outputs the required phase-shifted images of the reference signal are then taken. In practice, n = 4, i.e. a phase increment of 45 degrees, has proven itself to be sufficient.

When monitoring faults, it must be taken into account that two types of disturbances are possible:

• - Receiving a signal is considered an "external disturbance" referred to, which does not come from the plaque, however is evaluated as such by the recipient,
• - As a "malfunction" any type of defect Viewed plant, which has the effect that an Emp catch signal from the badge does not lead to the alarm would.

The anti-theft alarm device according to the invention contains devices for monitoring for both types of malfunctions, which are shown in principle in FIG. 4.

29 represents the entire receiver without blocks 12 and 13 of FIG. 1. In 30 the transmitter is composed of blocks 1 , 2 , 3 and 11 of FIG. 1. In addition, there is the test converter 26 , 27 and 28 , which works just like the badge 4-6 , but receives its operating voltage from the outside. The test converter is conveniently combined with the receiver antenna in one housing.

The transmitter can be switched on and off by means of an activation voltage which is supplied via the switch 31 . Likewise, the test converter can be switched on (activated) and switched off by means of the operating voltages supplied via the switch 32 . Finally, the receiver signal is optionally passed to one of the memories 34 , 35 or 36 via the switch 33 and stored there.

The interaction of the components of the theft warning direction is broken down in time into three bars, which are repeat cyclically.

In the first cycle step, external faults are checked. The switches 31 to 33 in FIG. 4 are in switch position 1 . In this position the transmitter 30 and the test converter 26-28 are switched off (see also Table 1). If the receiver 29 receives a signal in this cycle, it can therefore only be an external interference signal. This message from the recipient is stored in switch 34 via switch 33 . The memory holds the message "External fault signal present" at its output until the end of the cycle.

At the end of the cycle time, all switches are synchronized by one position. In the second cycle, there is a check for business interruptions. Transmitter 30 and Prüfumset zer 26-28 are switched on. Since the test converter behaves like a badge when the system is ready for operation, the receiver must receive and report a signal. This is recorded via switch 33 in the memory 35 , the inversion of the level at 37 ensuring that an error state, here "no signal", is represented by a positive voltage in the case of the memory 34 . With this cycle all components of the anti-theft alarm system are continuously monitored with a few exceptions (e.g. the optical and acoustic signal generators).

In the third cycle, all switches are in position 3 . The transmitter and receiver are switched on, the test converter is not active. In this cycle, a received signal can only come from the badge and means that after the theft alarm, the state is recorded in the memory 36 . It is expedient to logically link the output voltages of the memories in such a way that the presence of a fault prevents the display of an alarm in order to prevent false alarms. The alarm and interference signals prepared in this way are fed to the signal transmitters and displays ( 13 in FIG. 1). The acoustic message of a malfunction or an alarm can be given by outputting a spoken text, for which commercial circuits can be used for speech synthesis.

The switches 31-33 periodically rotate synchronously, so that the clocks are repeated cyclically. In the case of large rooms to be monitored, it may be necessary to use several receivers in parallel due to the limited range of the receivers. In this case, additional test cycles for these additional recipients are added; the switches must then be expanded to include the required switching positions. At the end of each cycle, the memories 34-36 are reset.

In Fig. 4, the switches for better understanding ses because of rotating mechanical switches Darge presents. In the practical training of the anti-theft device, commercially available electronic circuits are used for this.

Table 1

Claims (5)

1. Theft warning device consisting of a transmitter that surrounds the area to be protected from theft with a high-frequency magnetic field, a badge attached to the goods to be protected from deprivation, which receives the magnetic field and sends a signal again by means of a frequency divider, and a receiver with optical / Acoustic displays for this signal, characterized in that the theft warning device contains a correlator ( 10 ) for preventing the reception of interference signals not originating from the badge, which correlator ( 10 ) receives the signal arriving in the receiver with a reference signal derived from the transmitter by frequency division ( 11 ) correlated with the output signal of the gate correla is rendered un dependent on the phase position of the received signal that a plurality of correlator (14-16) connected in parallel and are provided with reference signals under schiedlicher phase position (17). 2. Theft warning device according to claim 1, characterized in that the correlator ( 10 ) is designed as a binary corrector, the received signal being converted by "hard" limitation into a binary signal (digital signal) ( 19 ), the process of multiplication by an EXCLUSIVE- OR operation ( 20 ) is replaced and the phase shifts of the also binary reference signal by means of a shift register ( 25 ) who executed. 3. Theft warning device according to claim 1 or 2, characterized in that after the process of correlation tion (consisting of multiplication ( 14 ) and integration ( 16 )), the output signal of the integrator is compared with a positive and a negative threshold, thereby simultaneously Both signals in the phase range 0 to 180 degrees and signals in the range 180 to 360 degrees can be detected, and thus the number of required correlator branches can be halved. 4. Theft warning device according to claim 1, 2 or 3, characterized in that for the detection and display of interference signals and operational malfunctions of the receiver ( 29 ) and the transmitter ( 30 ) by a test converter ( 26-28 ) acting like the badge, by memory ( 34- 36 ) and periodically rotating (electronic) switches ( 31-33 ) with at least three switch positions such that the operation of the anti-theft device runs in cycles consisting of at least three cycles:

• 1. a clock within which the converter (26 - 28) and the transmitter (30) are turned off, so that only any existing, external noise is received, stored and displayed for the duration of a cycle.
• A second cycle, within which the transmitter ( 30 ) and the test converter ( 26-28 ) are switched on, so that when the anti-theft alarm device is intact, a signal is received and stored, the absence of which indicates a malfunction.
• A 3rd cycle, within which the test converter ( 26 - 28 ) is switched off and the transmitter ( 30 ) is switched on, so that signals originating only from the badge ( 4-6 ) are received and stored, which triggers an alarm display.

5. Theft alarm device according to claim 4, characterized characterized in that one or more of the fault and Alarm messages by using circuits for Generation of synthetic speech signals as spoken Text can be output through a loudspeaker.