DE202015000559U1 - Anti-theft system for detecting RFID-marked objects - Google Patents

Abstract

System for determining RFID-marked objects, in particular configured as an anti-theft system for arrangement in the entry / exit area of department stores, supermarkets and similar objects, the system comprising at least one UHF RFID reader and at least one UHF RFID array connected thereto characterized in that the array (3) has three switchable states defining three separate reading zones (41, 42, 43), the outside reading zone (41) and the inside reading zone (43) being severely separated from each other and in that the array (3) consists of four radiator elements (71, 72, 73, 74) and a feed network (8).

Description

The invention relates to a system for detecting RFID-marked objects, in particular designed as anti-theft system for arrangement in the entrance / exit area of department stores, supermarkets and similar objects, the system comprising at least one UHF RFID reader and at least one UHF connected thereto RFID array.

Systems for detecting articles marked with RFID assemblies are already available in numerous designs. A typical example is anti-theft systems, which are usually arranged at the entry or exit area of department stores, supermarkets and similar objects and known as so-called EAS (Electronic Article Surveillance) theft protection. Conventional EAS facilities consist of so-called gates. These are based on large loop antennas, which generate an alternating magnetic field in front of them and are fed by readers / drivers, which are predominantly arranged under the antennas. Typical operating frequencies of such theft systems are 8.2 MHz and 130 kHz, respectively. If a transponder is located in the field of the gate antennas, the system can trigger acoustic and / or visual signals and thus an obvious warning about a currently suspected theft. A major disadvantage of these systems, however, are the short ranges, because the magnetic field decreases rapidly with the distance. Therefore, transponders can usually only be detected at distances of up to 1.5 m. As a result, these gates are always placed immediately in the middle of the entrance or exit areas so that they are always visible and actually encourage potential thieves to move past these gates with sufficient clearance.

In WO 2011/035 256 A2 describes a "beamforming" and localization system based on UHF-RFID. With this technical solution, it is possible to locate transponders by means of "beamforming" of the reader antenna and to detect so-called "marker tags" that are in fixed positions. As soon as new transponders from the same "Beamforming" place respond with the "Marker Tags", they are immediately and uniquely assigned. However, this system also requires so-called "Calibration Nodes" and an already complex data processing to realize the function of "beamforming".

Out US 5,708,423 A is a so-called "zone-based asset tracking and control system" known. This system is based on two successive gates that can determine the direction of a moving transponder, with the gates having two separate reading zones.

The object of the invention is to provide a designed as a theft protection UHF RFID system, which has a greater reading range over previously known systems, so that the antenna at greater distances from the input or output range, z. B. integrated in a ceiling or wall and thus not visible, can be arranged. At the same time, the system should convey without doubt "Marker Tags" and "Calibration Nodes" a clear information whether transponders have passed the entrance or exit area or not. Furthermore, a simplified structure is to be achieved by the system consists of only one unit, preferably with several separate and "Beamswitching" based reading zones.

This object is achieved by the array having three switchable states defining three separate read zones, the read zone being outwardly separated and the read zone inwardly being severely separated, and the array consisting of four radiator elements and a feed network. Preferably, the array is designed so that the inner radiator elements are fed with greater power (eg four times the power) than the outer radiator elements and that the sequential phase difference between the radiator elements is + X ° or -X ° when the array looks in the outer or inner business area and is 0 ° when the array is looking straight ahead and X is between 0 ° and 360 °. Alternatively, the sequential phase difference between the radiator elements may be + 90 ° or -90 ° if the array is looking in the outer and inner domains, and 0 ° if the array is looking straight ahead. Further alternative variants and advantageous embodiments are the subject of subclaims, whose technical features are explained in more detail in the embodiment.

The anti-theft system according to the invention can for example be integrated into the ceiling of a shop and is therefore not visible. The system is based on conventional UHF RFID transponders, the z. B. in a textile store as labels on clothing pieces and may be present.

The typical reading ranges of the previously known UHF RFID systems are more than 10 m and thus allow remote positions of the UHF anti-theft system.

A typical UHF RFID system consists of a reader and one or more antennas connected by coaxial cable. The use of a typical system as theft protection at the exit of a store is due to the wide 3dB opening angle of usually 70 °, the a commercial UHF RFID antenna has unfavorable. Because this would, if the antenna z. B. positioned on the ceiling of the exit, and many other transponders detected in the business. As a result, no firm statement could be made as to whether a transponder is actually being moved out of business. Similarly, even antennas with a small 3dB opening angle of 30 ° can not realize a clear statement as to whether a transponder is still in the shop or already at the exit.

These problems are now overcome by the system according to the invention consists of a UHF RFID reader and a specifically designed antenna array. In this case, the antenna array is integrated in a housing and can switch its directional diagram based on the control signals of the reader, preferably to allow three different directional diagrams. The antenna control signals are preferably transmitted via the same coaxial cable, but they can alternatively be transmitted via separate lines between the reader and antenna. The decision on where to place a transponder is based on a switch-beam antenna array, which has particularly narrow side lobes and thus enables an extremely high degree of separation between the transponders that are located in the interior of the store and in its outer area.

An embodiment of the anti-theft system according to the invention will be explained in more detail with reference to the drawing. Show it:

1 the structure of a known as prior art gate for theft protection

2 a variant of the structural design of the anti-theft system

3 the basic operating principle of the system according to the invention

4 the structure of the antenna array as a stylized block diagram

5 an example (table) of the power distribution between the radiator elements

6 an example (table) of the phase relationship between the radiator elements

1 shows a stylized representation of the structure of the known from the prior art and designed as theft protection EAS facilities in the form of so-called. Gates. These gates are based on large loop antennas 1 which generate a changing magnetic field in front of them and readers 2 are fed, the predominantly below the antennas 1 are arranged.

2 shows a specific embodiment of the anti-theft system according to the invention. The array 3 that with a UHF RFID reader 5 is in operative connection, is umhaust with a housing and can thus be mounted on a not shown here wall or ceiling or on similar sections of the objects to be monitored. About recesses in the housing looks the array 3 with three differently oriented reading areas into the surroundings, these separate reading areas subsequently being lobes because of their contour 41 . 42 and 43 be designated.

3 shows the basic operating principle of the system. As a result, it is an array 3 for example, on the ceiling in the entrance / exit area 6 a business and with a UHF RFID reader 5 connected. The array 3 looks with a first club 41 in the outdoor area of the store, a second club 42 looks down into the middle of the area to be monitored and a third club 43 looks in the interior of the business. The reader 5 has at each time note with which club 41 . 42 or 43 the specific transponder is read in each case. Thus, transponders that are located indoors, only from the club 43 read and thus trigger no alarm. Transponder, recently with the club 43 and now with the club 42 read, get a special status in the system as they move towards the exit. Transponder with the club 41 be read, trigger an alarm immediately. Thus, the decision as to whether a transponder leaves the store is based on a dynamic switching of the directional diagrams of the reading areas 41 . 42 and 43 and a real-time analysis of the behavior of the transponders in the input / output area 6 of the business.

In order to ensure trouble-free operation of the entire anti-theft system, the reading areas required by the guideline clubs must be 41 and 43 be formed, be well separated from each other. This is dictated by the design of the antenna array.

A special modification occurs when clothing or other items with transponders are facing out-door stores to attract customers. These transponders can be constantly from the club 41 to be watched. Unless one of the goods marked with these transponders is brought into the store by a customer and thus by the club 42 and / or the club 43 is read, the system will not trigger an alarm. However, once a product is out of the range of club 41 disappears and not from mace 42 or club 43 is to be detected, the system will trigger an alarm.

4 shows the block diagram of the antenna array. It consists of four radiator elements 71 . 72 . 73 and 74 , from a food network 8th and from an input port 9 , The radiator elements 71 to 74 can be realized, for example, as patch antennas. Likewise, but also other antenna concepts can be realized for this purpose, for. B. dipole antennas. The food network 8th is for power distribution and phase difference between the radiator elements 71 to 74 responsible.

By feeding the antenna elements with signals that have different phase, the array becomes 3 swing its main club in different directions. This may have the disadvantage that - if the directional diagram changes too much (pivots) - and the side lobes of the radiation pattern increase and cover unwanted reading areas. This would mean that - if z. For example, the array 3 with its head lobe looking towards business outside area - the antenna lobe rises and looks towards business interior area. Thus, transponders that are located there would be detected and trigger a false alarm. In order to minimize the side lobes, it is proposed as an embodiment that the feed network 8th in addition to the phase distribution also implements a power distribution in which the outer radiator elements 71 and 74 with a quarter of the power of the inner radiator elements 72 and 73 be fed.

5 shows an example of how the power between the radiator elements 71 to 74 is distributed, for example, if the total available power is 1 W. This power distribution guarantees suppression of the side lobes, thus ensuring that the read ranges 41 and 43 are clean from each other.

For the pivoting of the main lobe of the directional diagram, the individual radiator elements 71 to 74 fed with different phases. Any equal sequential phase difference will cause a pan. To ensure a practical realization of the pivoting, a phase difference of 90 ° is selected.

6 shows an example of the phase angle of the signals with which the radiator elements 71 to 74 be fed to realize the different reading zones indoors and outdoors. Since the phase repeats after 360 °, any further example with 90 ° sequential phase difference will give the same result. The value of 90 ° was chosen because there are different high frequency methods to realize this phase difference. It is possible to use a Buttler matrix or a Saleh divider.

The system for detecting RFID-marked objects described above is able to ensure a very good selectivity between the transponders in the interior and exterior of department stores, supermarkets and similar objects. This results in the preferred embodiment with three reading zones 41 to 43 a particularly accurate detection.

However, it is sufficient for an antitheft system in itself if the system has only one reading zone 41 or two reading zones 41 and 43 respectively. 41 and 42 uses.

LIST OF REFERENCE NUMBERS

1

2

Loop antenna according to the prior art

3

Reader according to the prior art

4

array

41

Club / Reading area outside area

42

Club / reading area transition area

43

Club / reading area inside area

5

UHF RFID Reader

6

Input / output area of the object to be monitored

71

Radiator element outside

72

Radiator element inside

73

Radiator element inside

74

Radiator element outside

8th

Feed network

9

input port

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2011 (035256 A2 [0003]
• US 5708423 A [0004]

Claims (11)

System for determining RFID-marked objects, in particular configured as an anti-theft system for arrangement in the entry / exit area of department stores, supermarkets and similar objects, the system comprising at least one UHF RFID reader and at least one UHF RFID array connected thereto exists, characterized in that the array ( 3 ) has three switchable states, the three separate reading zones ( 41 . 42 . 43 ), with the reading zone facing outwards ( 41 ) and the reading zone inside ( 43 ) are strongly separated from each other and that the array ( 3 ) of four radiator elements ( 71 . 72 . 73 . 74 ) and a feed network ( 8th ) consists. System according to claim 1, characterized in that the power distribution to the radiator elements ( 71 to 74 ) is designed so that the inner radiator elements ( 72 . 73 ) with greater power than the outer radiator elements ( 71 . 74 ) and that the sequential phase difference between the radiator elements ( 71 to 74 ) + X ° or -X °, if the array ( 3 ) looks into the outer or inner business area and is 0 ° when the array ( 3 ) looks straight ahead and X is between 0 ° and 360 °. System according to claim 1, characterized in that the power distribution to the radiator elements ( 71 to 74 ) is designed so that the inner radiator elements ( 72 and 73 ) with four times the power of the outer radiator elements ( 71 . 74 ) and that the sequential phase difference between the radiator elements ( 71 to 74 ) + 90 ° or -90 °, if the array ( 3 ) looks into the outer or inner business area and is 0 ° when the array ( 3 ) looks straight ahead. System for determining RFID-marked objects, in particular configured as an anti-theft system for arrangement in the entry / exit area of department stores, supermarkets and similar objects, the system comprising at least one UHF RFID reader and at least one UHF RFID array connected thereto exists, characterized in that the array ( 3 ) has two switchable states, the two separate reading zones ( 41 . 43 ) and that the array ( 3 ) of four radiator elements ( 71 . 72 . 73 . 74 ) and a feed network ( 8th ), wherein the power distribution to the radiator elements ( 71 to 74 ) is designed so that the inner radiator elements ( 72 . 73 ) with greater power than the outer radiator elements ( 71 . 74 ) and wherein the sequential phase difference between the radiator elements is + X ° or -X ° when the array ( 3 ) looks into the outer or inner business area and X is between 0 ° and 360 °. System for detecting RFID-marked objects, in particular configured as an anti-theft system for arranging in the entry / exit area of department stores, supermarkets and similar objects, the system comprising at least one UHF RFID reader and at least one UHF RFID tag connected thereto Array consists, characterized in that the array ( 3 ) has only one state that has a read zone ( 41 ) and that the array ( 3 ) of four radiator elements ( 71 . 72 . 73 . 74 ) and a feed network ( 8th ), wherein the power distribution to the radiator elements ( 71 to 74 ) is designed so that the inner radiator elements ( 72 . 73 ) with greater power than the outer radiator elements ( 71 . 74 ) and wherein the sequential phase difference between the radiator elements ( 71 to 74 ) + X ° is when the array ( 3 ) looks in the outer business area and X is between 0 ° and 360 °. System according to one of claims 1 or 4 or 5, characterized in that the control and switching signals between reader ( 5 ) and antenna array ( 3 ) are transmitted on the same high-frequency coaxial cable or on separate lines. System according to one of claims 1 or 4 or 5, characterized in that the reader ( 5 ) is integrated in the antenna such that antenna and reader are designed as a common unit. System according to one of claims 1 or 4 or 5, characterized in that the reader ( 5 ) analyzes the phase of the transponder signal to achieve accurate positioning of the transponder. System according to one of claims 1 or 4 or 5, characterized in that a reader ( 5 ) with at least one and at most with up to 32 antenna arrays ( 3 ) connected is. System according to one of claims 1 or 4 or 5, characterized in that the array ( 3 ) uses a Butler matrix or a Salehteiler as a switching matrix to realize the phase differences of + 90 ° or -90 °. System according to one of claims 1 or 4 or 5, characterized in that the antenna in the input / output area ( 6 ) of the object to be monitored is positioned under the ceiling or integrated in the ceiling or positioned on the side wall or integrated in the side wall.

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