FR2836581A1 - Detection of a transponder label signal, especially for use in shops, etc., using a detection panel with antennae whose operating frequencies are continuously modulated to enable detection of a wider frequency range - Google Patents

Abstract

Method for detection of a radio-frequency transponder label using a detection panel (1) comprising at least a transmission antenna (10) with a transmission loop (11) and at least one receiving antenna (20, 30), wherein the operating frequency of both antennae is continuously modulated. The invention also relates to a corresponding device.

Description

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RADIO FREQUENCY LABEL DETECTION METHOD WITH CONTINUOUS MODULE SIGNAL, PANEL AND DEVICE FOR IMPLEMENTING THE SAME
OF THE PROCESS
The present invention relates to the field of detection of radio frequency tags in order to combat the theft of goods so marked.

 The present invention relates more particularly to a method for detecting a radio frequency label using at least one detection panel comprising at least one transmit antenna comprising at least one transmit loop and at least one antenna. reception comprising at least two reception loops.

 It is known in the prior art to produce detection panels comprising a transmission antenna comprising a transmission loop and at least one reception antenna, the transmission antenna or antennas using a pulsed signal.

 This system has the drawback of detecting labels which do not have a resonant frequency corresponding exactly to the desired value. Indeed, currently, due to the available manufacturing methods, it is not possible to manufacture self-adhesive labels all having exactly the same resonance value corresponding to the desired value. Thus, in a batch of self-adhesive labels for the detection of thefts in hypermarkets and supermarkets using the resonance frequency of 8.2 MHz, at least 5% of the labels have a resonance frequency with a frequency variation greater than 2% by compared to the theoretical frequency. However, the pulse signal detection systems of the prior art do not detect frequency variations greater than 2%. So,

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 approximately 5% of the self-adhesive labels are not detected by the pulse signal detection systems.

 It is of course possible to carry out a preliminary sorting of the labels, but this sorting then considerably increases the cost of manufacturing the labels.

 In addition, pulse signal detection systems are not immune to interference and cause a significant number of false alarms. Indeed, as soon as any device located near a detection antenna of such a pulsed signal system has, at least for a short time, a frequency identical to that detected, the system will cause the implementation alarm means.

 The present invention intends to remedy the drawbacks of the prior art by proposing a detection system having an enlarged operating frequency which makes it possible to use all the detection labels and which is not sensitive to parasites.

 To do this, the present invention is of the type described above and it is remarkable, in its broadest sense, in that the operating frequency of each antenna is continuously modulated, in order to allow all the tags to be detected. , even those which do not have a resonance frequency exactly identical to that of theoretical operation of the detection system.

 At least one reception antenna is preferably connected to a reception card comprising at least one digital BBD filter, in order to make it possible to detect a constant resonance signal.

 Said antennas are preferably positioned substantially in the same plane inside the panel.

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 A reception antenna preferably has at least two reception loops crossed at least once on itself at a crossing point.

 Said reception antennas preferably each have crossed loops whose crossing points are offset with respect to each other in a general direction of passage of the radiofrequency label.

 In an alternative embodiment, the reception antennas are connected to a single multiplexed reception card.

 When a plurality of detection panels are used, the modulation frequencies of said antennas of each panel are preferably modified in order to prevent any disturbance between two close panels.

 In addition, when at least one bi-antenna system is adjacent to a mono-antenna system according to the invention, said antennas of the detection panel or panels according to the invention are synchronized with the antennas of the adjacent bi-antenna system (s) ( s), in order to make said antennas of the detection panel or panels according to the invention compatible with this system.

 The present invention also relates to a detection panel for detecting a radiofrequency label by implementing the method according to the invention, as well as to a device for detecting a radiofrequency label for implementing the method according to the invention.

 Advantageously, a mono-antenna system according to the invention with a modulated signal makes it possible to detect labels which are not very precise because they have a large frequency variation. Such labels,

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 used for example in combination with a self-adhesive support, are less expensive to manufacture than wound labels working with single-layer or multi-layer ceramic capacitors, but they are also less precise.

 Advantageously also, the fact of using a technology close to that previously developed for bi-antenna systems at the level of the electronic cards of the mono-antenna system according to the invention (continuous modulated signal and non-pulsed signal) makes it possible to synchronize this mono-antenna system with other bi-antenna systems. In supermarkets or shops, it is therefore possible to have co-existing mono-antenna systems close to bi-antenna systems.

 By mono-antenna system means the use of a single panel for the transmitting antenna and the receiving antenna (s), while by bi-antenna systems M means the use of at least two separate panels, one for the emission, the other or the others for the reception.

 The invention will be better understood with the aid of the description, given below for purely explanatory purposes, of an embodiment of the invention, with reference to the appended figures: - Figure 1 illustrates a block diagram d 'A panel with two receiving antennas positioned on each side of a transmitting antenna, for implementing the method according to the invention; and - Figure 2 illustrates a block diagram of a panel with two receiving antennas superimposed next to a transmitting antenna, for the implementation of a variant of the method according to the invention.

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 The method according to the invention is a method for detecting a radio frequency label (100) using at least one detection panel (1), illustrated in FIG. 1, comprising at least one transmitting antenna (10) comprising at least one transmit loop (11) and at least one receive antenna (20,30). The transmitting and receiving antennas (10, 20, 30) being housed inside the detection panel (1), this panel constitutes a mono-antenna panel M, in the sense that those skilled in the art understand it today. today, as opposed to two-antenna detection systems, on the one hand, the transmitting antenna (s) and, on the other hand, the receiving antenna (s) are separate and are not housed in the same panel.

 The method according to the invention is characterized in that the operating frequency of each antenna (10, 20, 30) is continuously modulated, in order to avoid any disturbance between the respective fields of the panels.

 The panel (1) is positioned in a passage in order to allow the detection of the presence of a radiofrequency label (100) in said passage. The general direction of passage of the label (100) is illustrated by the arrow D.

 The transmitting antenna (10) is connected to an electronic transmitting card (16) and the receiving antenna (s) (20,30) are each connected to a receiving card (26,36). However, in an alternative embodiment illustrated in FIG. 2, said reception antennas (20, 30) are connected to a single multiplexed reception card (40). It is thus possible to position the system in an antenna such as that known from patent application FR 01/14793, incorporated here by reference.

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 Whatever the variant, the reception cards (26, 36, 40) each include at least one digital filter BBD (BUCKET BRIGADE DEVICE), preferably with a repetition rate of 1024 steps, in order to allow to detect a constant signal of resonance.

 It is important to note that this filter can be either mounted in cascade, or mounted so as to multiply the number of steps.

 Only the signals having a very precise period, and therefore the label signal, are considerably amplified by looping back and therefore better detected. Spurious signals which may have for a short time a frequency identical to the resonance frequency of the labels, but not having the same precise period, do not pass through the filter and do not generate an alarm. The false alarm rate is thus considerably reduced compared to that of the pulsed signal systems of the prior art.

 This principle makes it possible to have a greater detection of approximately 1.20 meters on each side of the panel for a rectangular self-adhesive label (100) of 4 cm by 4 cm.

 The coexistence of modulated signal panels can be done either by synchronization cable, or by changing the modulation frequency of each panel close to each other so that they do not disturb each other. We can indeed install the first panel with a modulation frequency of 78 Megahertz, the second with a modulation frequency of 82 Megahertz, the third with an operating frequency of 85 Megahertz and we can return for the fourth panel on a frequency of modulation of 78 MHz, the latter being far enough from the first panel so that they do not interfere, and so on.

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 In their application to the technology currently used in supermarkets using an operating frequency of 8.2 Megahertz, all of these panels of course have an operating frequency of 8.2 Megahertz and can all detect the same labels. It is also possible to use another operating frequency.

 The device for implementing the method thus makes it possible to detect labels (100) by operating on a central frequency of 8.2 Megahertz, but with the possibility of widening this frequency band between for example 7.4 Megahertz and 8.6 Megahertz.

 By using on the single antenna system electronic receiving cards with continuous modulated signal with a filter favoring the signal of the label (100), it is thus possible to improve the signal to noise ratio and allow better detection of the self-adhesive labels.

 The antennas (10, 20, 30) are positioned exactly in the same plane or in planes offset by at most a few centimeters (maximum 10 centimeters), the offset being effected in a direction perpendicular to the direction D.

 In the variant illustrated in Figure 1, the receiving antennas (20,30) are positioned on each side of the transmitting antenna (10), while in the variant illustrated in Figure 1, the receiving antennas (20,30) are positioned one against the other, on the same side of the transmitting antenna (10).

 The reception antenna (s) (20,30) has (s) respectively at least two reception loops (21,22, 23; 31,32) crossed at least once on itself at a crossing point (24, 25; 34).

 Preferably, a receiving antenna (20) has a regular triple loop and the other

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 receiving antenna (30) has a regular double loop. In a loop, each lobe has substantially the same surface.

 Said receiving antennas (20,30) each have crossed loops whose crossing points (24,25; 34) are offset with respect to each other in the general direction D of passage of the radiofrequency label (100).

 Thus, knowing that as a general rule at the point where the loops intersect, there is a detection hole, a label (100) passing along the panel may be located in the intersection (34) of the loop of the first receiving antenna (30) and not being detected, but being at the same level with the ground when passing through the second receiving antenna (20), it will then be in the middle of the loop (22) and will therefore be detected.

 The radio frequency label detection device (100) for implementing the method according to the invention consists of at least one panel (1) located near a passage that is to be controlled. The panel (1) can thus be positioned in the middle of the passage, for example between two cash registers of a store. The panel (1) thus makes it possible to detect the passage of labels both in front and behind, that is to say to the left or to the right of the panel according to the general direction of passage D.

 The radio frequency label detection device (100) for implementing the method according to the invention preferably consists of a plurality of detection panels (1). The modulation frequencies of said antennas (10, 20, 30) of each panel (1) are then modified in order to prevent any disturbance between

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 two close panels. The panels can then coexist without particular synchronization.

 In addition, when dual antenna systems are located near the antennas (10,20,30) of the one or more detection panels (1), these antennas (10,20,30) can be synchronized with the antennas of the or adjacent two-antenna systems, in order to make said antennas (10, 20, 30) of the detection panel or panels (1) compatible with this or these two-antenna systems.

 The invention is described in the foregoing by way of example. It is understood that a person skilled in the art is able to carry out different variants of the invention without going beyond the scope of the patent.

Claims (10)

1. Method for detecting a radio frequency label (100) using at least one detection panel (1) comprising at least one transmitting antenna (10) comprising at least one transmission loop (11) and at least one receiving antenna (20,30), characterized in that the operating frequency of each antenna (10,20, 30) is continuously modulated.  2. Method for detecting a radio frequency label (100) according to claim 1, characterized in that at least one reception antenna (20,30) is connected to a reception card (26,36) comprising at least one filter digital BBD, to detect a constant resonance signal.  3. A method of detecting a radio frequency label (100) according to claim 1 or claim 2, characterized in that said antennas (10,20, 30) are positioned substantially in the same plane.  4. A method of detecting a radio frequency label (100) according to any one of claims 1 to 3, characterized in that a reception antenna (20,30) has at least two loops (21,22, 23; 31 , 32) of reception crossed at least once on itself at a crossing point (24,25; 34).  5. A method of detecting a radio frequency label (100) according to claim 4, characterized in that said receiving antennas (20,30) each have crossed loops whose crossing points (24,25; 34) are offset relative to each other in a general direction D of passage of the radio frequency label (100).  6. A method of detecting a radio frequency label (100) according to any one of claims 1 to 5, characterized in that said antennas (20,30) of <Desc / Clms Page number 11>  reception are connected to a single multiplexed reception card (40).  7. A method of detecting a radio frequency label (100) according to any one of claims 1 to 6 using a plurality of detection panels (1), characterized in that the modulation frequencies of said antennas (10 , 20, 30) of each panel (1) are modified in order to prevent any disturbance between two close panels.  8. A method of detecting a radio frequency label (100) according to any one of claims 1 to 7, characterized in that said antennas (10,20, 30) of the detection panel (s) (1) are synchronized with the antennas at least one adjacent bi-antenna system, in order to make said antennas (10, 20, 30) of the detection panel or panels (1) compatible with this bi-antenna system.  9. Detection panel (1) for detecting a radio frequency label (100) by implementing the method according to any one of claims 1 to 8.  10. Device for detecting a radio frequency label (100) for implementing the method according to any one of claims 1 to 8.