DE19505493A1 - Electronic identification and detection method e.g. for department store goods - Google Patents

Abstract

The method is for objects having passive resonators (MF-tags) connected together to form arrays by means of electromagnetic fields. The resonators are targeted and coded in a contactless manner. The MF-tags are remotely coded and detected via a computer unit (1). Modulation signals for the detection process are generated by a detection unit (6). They are generated by a coding unit (2) for the coding process. The output signals of the detection unit are evaluated and the detection results (identification) are displayed.

Description

The invention relates to a method for elec tronic marking and identification of objects according to the preamble of claim 1.

There are already electronic marking devices of objects known to monitor goods movements are used in department stores. These facilities are attached to the goods and cause the delivery of a acoustic signal when the entrance / exit gate of the Department store with the labeled goods is passed.

In U.S. Patent 4,920,335 an electronic article reference is published guard proposed a planar resonator contains. The resonator (parallel resonance circuit) is on the applied to be marked article.  

An alternating electromagnetic field with a given frequency range enables the resonant current distribution to be increased detect and thus marked articles from those without Distinguish distinguishing marks. The resonant behavior of the The indicator is switched off electrically in that a second electromagnetic field of different frequency (burn-out Frequency) the resonator circuit due to line interruption of a microwave line resonator inoperable should. The mark remains on the article.

Also in US 4,728,938, US 4,567,473, US 4,498,076 Systems described with which individual resonators are recognized and can be turned off.

The disadvantage of these solutions is that only one bit for Coding is available and therefore just a simple one Decision is possible, namely the license plate is present the or does not exist. It is not an activation of the Resonators possible. It's through the burn-out frequency only irreversible switching off of the resonator possible. This is the applicability of the proposed solutions strongly limited. It also becomes a comparatively high one electrical power required.

There are also in DE 30 23 446 C2, DE-OS 19 05 008, US 3,752,960 method for the electronic identification of Items described where a plurality of Resona is used for coding objects. The proposed resonators have no planar structure and are therefore limited in use. In DE 19 05 008 is an elaborate technology with discrete Components provided. It will essentially be procedure and circuits for the detection of pre-coded resonance circuits described. The solutions see the use of transmitters,  Wobble generators, phase detectors and the like. In the US 3,752,960 and DE 30 23 446 C2 is not a non-contact Activation / deactivation possible, it is direct access to the object necessary.

DE 43 38 554 A1 describes the arrangement of a large number of Resonators in an array for flexible coding described according to the application. Any resonator consists of a detection resonator with a defined one Detection frequency and from a burn-out resonator with the defined burn-out frequency. By connecting electromagnetic fields with selected frequencies the resonators are encoded in a targeted and contactless manner.

The invention has for its object a method for electronic identification and identification of To create objects with which on the basis of Resonator arrays are inexpensive and reliable Securing documents and objects of all kinds against Counterfeiting and abuse is guaranteed.

The task is characterized by the characteristic features of the Claim 1 solved. By using non-contact encodable resonators, which are combined in an array are, it is guaranteed with the procedure, inexpensive Realize security systems for many areas of application. There are no batteries or semiconductor circuits for the Information carrier needed. The planar structure of the Informa tion carriers and their small geometric dimensions allow a wide application, for example certificates, Documents, tickets of all kinds before reprint, for example be protected by color copiers. It will be the cost-effective electronic coding of paper stickers possible or labels and their non-contact electronic  Identification. In contrast to known goods security systems where only the simple deactivation (1 bit) is possible, depending on the application Multi-bit encodings and recodings take place. The procedure is through the contactless coding and detection wear-free. Only one is used for coding and recoding low electrical power of z. B. <1. . . 2 watts and for that Identify e.g. B. <0.01 watts required.

Further advantageous embodiments of the invention result itself from the subclaims.

The invention is described below in one embodiment explained in more detail. In the accompanying drawing:

Fig. 1 is a schematic representation of the construction of a system for marking and identification for implementing the method,

FIG. 2 shows the schematic structure of MF tags (multi-frequency tag)

Fig. 3 shows the schematic structure of a Einzelresonators (upper side),

Fig. 4 shows the schematic structure of an individual resonator according to Fig. 3 (bottom) and

Fig. 5 shows the electrical equivalent circuit diagram for one of the individual resonators on a MF-tag shown in FIGS. 3, 4.

According to the representation in FIG. 1, the identification system for implementing the method consists of a personal computer 1 which , via a coding device 2 with a switching matrix 3 , consists of, for example, twelve LF and twelve RF coils 4 , 5 , for contactless coupling of electromagnetic energy, and via a detection unit 6 is connected to a transmitting and receiving device 7 for contactless reading of MF tags 8 .

The personal computer 1 (or a corresponding computer unit) is used to control the coding and detection, to generate modulation signals for the detection and coding, to evaluate the output signals of the detection unit 6 and to present the results of the identification.

In the detection unit 6 , the control signals from the personal computer 1 are converted into RF-FM transmission signals of, for example, 3 to 20 MHz, and the phase detection of the receiver signals is carried out.

In the coding unit 2 , the control signals from the personal computer 1 are in NF energy of the frequency f₀ of, for example, 125 kHz for activation and in HF energy of the frequencies f _k (k = 1, 2, 3,... N) of, for example 3 to 20 MHz implemented to deactivate the MF tags 8 via the switching matrix 3 .

The contactless coupling of magnetic energy into the individual resonators 9 of the MF tags 8 via the coupling field 3 effects the coding of the MF tags 8 through targeted electrothermal “destruction” of “predetermined breaking points” 12 .

As shown in FIG. 2, the MF tags 8 consist of twelve individual resonators 9 . The individual resonators 9 are as shown in FIGS . 3, 4 from example, a planar coil 10 made of copper on the top of a polypropylene film 14 , a capacitor, formed from the capacitor plate 11 on the top of the film 14 and the capacitor plate 15 on the bottom the film 14 , and from predetermined breaking points 12 , 13 formed on the top and bottom of the film 14 . Points a, b are in each case through-contacted.

5 shows the electrical equivalent circuit diagram of an individual resonator 9 forming a planar oscillating circuit . In the original state, each individual resonator 9 is inactive. When activated, the predetermined breaking point 12 is electrically interrupted by targeted contactless coupling of electromagnetic energy. The resonance circuit is thus functional and detectable. When deactivated, the predetermined breaking point 13 is switched , analogously to the activation process. The resonant circuit is inactive again and therefore no longer detectable. The plated-through holes A, B correspond to points a, b in FIGS. 3, 4 on the top and bottom of the film 14 .

The procedure is described below using the example of the fuse Counterfeit tickets for major events explained.

To buy tickets for major events, such as trade fairs, concerts, sporting events, before counterfeiting, e.g. B. electronically using a color copier, the ticket is provided with an MF tag 8 . It can therefore be used for admission control. Due to its planar structure and the very small layer thickness of 50 to 100 µm, for example, the MF Tag 8 can be inserted into an admission ticket consisting of two layers of paper without great effort. The paper layers are then glued.

The resonators 9 of the MF tags 8 are initially inactive. The predetermined breaking points 12 formed by conductor structures with a small cross section short-circuit the coils 10 , the circuit shows no resonance behavior ( FIG. 5).

When the ticket is sold, a certain code is applied to the MF tags 8 , depending on the type of event, by activating part of the individual resonators 9 of the MF tags 8 in that low-frequency electromagnetic energy of the frequency f₀, for example of 125 kHz, via the Excitation coils 4 of the switching matrix 3 are coupled into the planar coils 10 of the resonators 9 to be activated. The admission ticket can be placed directly on the switching matrix 3 ( Fig. 1). The electromagnetic coupling of the coils 4 of the switching matrix 3 with the MF tag 8 induces a current in the respective planar coil 10 which flows through the predetermined breaking point 12 so that it is destroyed electrothermally. So that the resonator 9 is active and shows excitation with the resonance frequency f _k , which has a much higher value than the burn-out frequency f Burn, its resonant circuit behavior. The resonance frequencies f _{k of} the individual resonators 9 are determined by the planar coils 10 and the capacitors, each formed from the capacitor plates 11 , 15 . The respective predetermined breaking point 13 of the resonators 9 ( FIGS. 3, 5) is not damaged when the burn-out frequency f Ein acts, because the capacitors 11 , 15 have high impedance at the burn-out frequency f₀. The transmission signal required for the activation of the resonators 9 is generated by a control and evaluation unit, here by the personal computer 1 ( FIG. 1), converted digitally / analogously, amplified and by means of a corresponding logic, here z. B. the coding unit 2 ( Fig. 1), to the respective excitation coils 4 of the switching matrix 3 , which activate the intended resonator 9 . The seller of the admission ticket can then use the detection unit 6 to check the correctness of the code applied.

The correctness of the code applied to the admission ticket is also checked at the entrance to the event by the MF tag 8 in the admission ticket in the detection unit 6 ( FIG. 1) in a detection area with n resonance frequencies f _k (k = 1, 2, 3 ,... n) is excited electromagnetically. The exciting signal is wobbled in the range of the resonance frequency f _k , z. B. by ± 5 to 10%. The code that has been applied to the admission ticket is determined by the fact that, at certain frequencies f _{i of} the frequencies f _k, the electromagnetic field between the schematically illustrated transmitting antenna 7 a and the schematically illustrated receiving antenna 7 b of the transmitting and receiving unit 7 ( FIG . is 1) is changed by the activated resonators. 9 These changes are filtered out as phase jumps in the detection device 6 with the aid of a phase detector with connected bandpass filter, converted analog / digital and evaluated by the personal computer 1 . If the code of the admission ticket determined in this way does not match the code specified for the event, the person concerned will not be admitted. If an additional coding device 2 with a switching matrix 3 is installed in the inlet area, which is tuned to the resonance frequencies f 1 to f _n , then the admission ticket can be canceled after the entry has taken place. Analog to the activation process, electromagnetic energy is coupled via the excitation coils 5 into the MF tag 8 in order to electrothermally disrupt the predetermined breaking points 13 of the resonators 9 activated at the issue of the admission ticket with the frequencies f _i ( FIG. 5 ).

If necessary, the admission ticket can only be recoded, to give the person concerned access to a separate Area within the event (e.g. VIP room) enable. There the card with the described The method is first detected and then devalued.

Any changes that appear on the ticket Information carriers are made completely contactless. The information carrier is extreme inexpensive and flexible, and the process works wear-free.

The performance features of the MF tags 8 can be adapted to the various applications within wide limits, in particular with regard to the geometric dimensions, the code width, the thermal and mechanical properties. The code width of twelve bits with 4096 possibilities can be extended to code widths of up to 64 bits if the application should require it.

Reference list

1 personal computer / computer and control unit
2 coding unit
3 switching matrix
4 pickup coil (LF coil)
5 pickup coil (RF coil)
6 detection unit
7 Sending and receiving unit
8 MF days
9 single resonator
10 planar coil
11 capacitor plate
12 predetermined breaking point
13 predetermined breaking point
14 polypropylene film
15 capacitor plate

Claims (3)

1. A method for electronic marking and identifying objects using passive, connected to form arrays resonators (MF-day) by means of electromagnetic fields, wherein the resonators are specifically and non-contact coded, characterized in that a computer unit (1), the MF tags ( 8 ) coded and detected, the modulation signals for the detection by means of a detection unit ( 6 ) and for the coding by means of a coding unit ( 2 ) are generated, the output signals of the detection unit ( 6 ) are evaluated and the results of the detection (identification) are shown. 2. The method according to claim 1, characterized in that on the one hand the control signals of the computer unit ( 1 ) in the coding unit ( 2 ) in LF energy for activation and in HF energy to deactivate the MF tags ( 8 ) implemented and via a Coupling field ( 3 ) is coupled contactlessly into the resonators ( 9 ) of the MF tags ( 8 ) and the MF tags ( 8 ) are coded and that on the other hand the control signals of the computer unit ( 1 ) in the detection unit ( 6 ) in HF-FM Transmitted signals are converted and the receiver signals are phase-detected, and that the MF tags ( 8 ) are detected in a non-contact manner in a transmitting and receiving unit ( 7 ). 3. The method according to claim 2, characterized in that the switching matrix ( 3 ) is formed from a plurality of LF and HF coils ( 4 , 5 ), each of which in particular the number of resonators ( 9 ) of the MF tag ( 8th ) corresponds.