NL9300290A - Reading multiple detection labels in an interrogation field at the same time, and determining the position of these labels. - Google Patents

Description

Reading multiple detection labels in an interrogation field simultaneously, and determining the position of these labels.

The invention relates to an identification system in which the strength differences of received signals are used to detect not only the strongest signal, but also weaker transponder signals.

In wireless and battery-less identification systems, as described, for example, in applicant's patent 176404, EP 030127 (Texas Instruments), or WO90 / 14736 Trovan, as soon as multiple labels are active within the interrogation field, only the strongest transponder is detected. If multiple transponders cause signals in the receiver that differ relatively little, the receiver will not detect any signal. This effect can occur especially in systems where the detection distance is large. This can cause problems in applications where it is not always possible to separate the transponders sufficiently spatially. For example, in systems to selectively give access to ski lifts by means of transponders, it is often not possible to prevent multiple transponders from being within reach of the same reading unit due to the pressure.

Different solutions are used in order to be able to detect several transponders that are simultaneously in the range of the interrogator.

It is known from the patent EP 0285419 of Sattelite Video systems, that entire search trees are then run through to select one of the transponders present, after which a subsequent transponder is selected, and so on, until all transponders are selected.

A drawback of this method is that, on the one hand, the transponders become very complicated, and on the other hand, the readout time becomes very long.

The solution according to US 5124699 Nedap, where, after it has been established that several transponders are active at the same time, a selection is made via a random waiting time, has the same drawbacks.

Another solution provides a transponder with a random pause time built in after the code is sent. Due to the arbitrary nature of the breaks, the length of which is preferably between, for example, 3 and 10 times the length of a code, the situation will occasionally arise that only one of the transponders present is active. Although this provides a simple system, the disadvantage of a long recognition time is even heavier here.

In the solution of EP 0161779 Senelco, when simultaneous reception of several transponders, an attempt is made to selectively switch off one active transponder.

Here too, the drawbacks are that the detection time increases, and that the system becomes complex.

The invention has a solution for simultaneously detecting multiple transponders within one interrogation field, without the transponders becoming more complex and without additional time being required to detect multiple responders.

Another problem that occurs with, for example, the access device of ski lifts is that it is not always clear that the skier who is at the front to be let through is also the one whose transponder is read.

The invention also makes it possible to determine the relative position of transponders.

It is generally known that the signal strength of the received signal has a relationship with the distance between the transponder and the antenna.

German Offenlegungsschrift DE 3714263 Goetting, describes a localization system in which a large field gradient is locally produced by controlling two transmit coils in counter phase. The sharp minimum of field strength is 0, so that in a well-defined place the transponder briefly stops generating code.

Obviously, this is not a good method to identify and locate multiple transponders simultaneously.

Another and more precise solution to the locating problem is described in applicant's EP 0257688, where a separate pilot tone is generated in the transponder, after which the position is determined by means of 8-shaped receiving antennas from the strength of the pilot tone. This very accurate method requires special features of the transponder and is therefore more complicated than the solution according to the invention.

An additional problem with the above locating methods is that the position of the transponder influences the result of the position determination, whereby errors can occur if the transponders are freely movable.

The position of the transponder is also determined by the invention, but with limited accuracy. The solution according to the invention is sufficiently precise to solve the sequence problem, such as can occur for instance with access to ski lifts.

The invention assumes that there are clearly measurable differences in strength between the signals that are received. This means that the number of transponders that can be read simultaneously is limited.

In practical applications this is not a limitation; due to the physical dimensions of the carriers of the transponders, there can seldom be more than, for example, three transponders within the range of the transceivers.

With a large receiving antenna, a lot of signal is received. However, there are a large number of possible transponder locations and positions that generate the same signal strength in the large receiving antenna coil. Due to the large coil, integration over a large area occurs. A small antenna coil will have this much less. However, less signal is picked up, as well as fewer interfering signals, so that a very good signal-to-noise ratio can still be achieved with very small, in the extreme case almost point-shaped receiving antennas.

Of course, the own noise contribution of the signal amplifier is important. With a small antenna, there is usually a considerable difference in the distance between a transponder and the small antenna. Since, in addition to the distance to the receiving antenna, the rotation of the transponder and the distance to the transmitting antenna also strongly influence the strength of the received signal, it may still occur that the strength differences of the transponder signals are still too small. By adding a second receiving antenna, which is located far from the first receiving antenna, the chance that this too will see too small differences in strength becomes very small. Moreover, in a dynamic environment the position of transponders is always different. A third or even fourth receiving antenna coil ensures that a strength difference is almost always received such that detection of the strongest signal is possible. Receiving this strong signal is essentially nothing that is done with the existing technique.

The very small receiving antennas of the invention create a greater difference in signal strength.

A simple multi-tag detection system could consist of many small receiving antennas with receivers. Because the small antennas maximize the distance differences between transponders and receiving antenna, there will often be sufficient difference in strength to detect the labels.

An improved solution assumes that once a strong signal is detected, the contribution that this signal makes to the total received signal can be eliminated, after which the weaker signal will appear, allowing two transponder codes to be detected almost simultaneously.

Eliminating this is not easy. Although the original code signal is fully known after detection, the code signals are distorted during their path from transponder to receiver. This deformation manifests itself mainly in rounding of the flanks. The distortion depends, among other things, on the signal strength. On the basis of this data, the best possible reconstruction of the contribution of the strongest responder signal to the total received signal can be determined and subtracted from it. The correlation between the two signals must be minimized. In this way, the artifacts remain small and a weaker transponder signal can emerge. This signal is now treated as the first strong signal, etc. Once detected, an attempt can be made to find a third signal. The signal on an antenna coil is often also present with a different strength on a different receiving antenna.

It is therefore also part of the invention to investigate, once a code signal has been detected, whether there is a correlation between this signal and the various other received signals. Minimizing the correlations makes it easier to detect the other transponder codes from the residual signals. Using the large transmit antenna as a receiving antenna, especially for this purpose, is very useful. A further improvement of the system is to provide the double, that is to say on either side of a passage. In particular, transponders that are located far away from all receiving antennas on one side of the passage can be easily detected by the receivers on the other side of the passage. The code and strength of each transponder signal as it enters each receiver antenna can thus be determined according to the invention.

The strength of the signal gives a collection of points where a transponder can be located. After all, the strength of the received signal is determined by: - the component of the field strength at the location of the responder, which is perpendicular to the plane of the transponder antenna; - the conversion efficiency of the transponder; - the distance between the transponder and the receiving antenna; - the angle between the plane of the transponder and the connection line from the transponder to the receiving antenna; - the angle between the plane of the receiving antenna and the connecting line from the transponder to the receiving antenna.

Each receiving antenna provides a different set of points where the transponder can be located. Due to the high degree of non-linearity in the relationships, the analytical solving of the many equations with many unknowns is very complex.

A numerical solution method in which a coarse grid of possible points where a transponder can be located, coupled with a limited number of turns of the transponder, provides a limited number of options for the position and position of the transponder for each antenna. Each receiver provides such a collection of possible transponder positions. The cross section of these collections then provides the current position of the transponders. Precisely because of the complex relationships that exist between the signal strengths and the position of the transponders, a solution method that uses neural networks quickly leads to useful results, and the self-learning nature of this solution is a particularly great advantage.

The invention is explained in more detail below with reference to figures.

Figure 1 shows an arrangement according to existing technique.

Figure 2 shows an embodiment according to the invention.

The large antenna coil 1 in Figure 1 has the function of both transmit and receive coil. Two transponders 2 and 3 located above this coil, although spaced far apart, still have the same distance from the antenna coil 1, so that the signal strength caused by each of the transponders in the coil will differ little.

In Figure 2, the transmitting antenna is again the large coil 1, but the small antenna 4 is used as a receiving antenna. The distance between transponder 3 and the receiving antenna 4 is clearly much greater than the distance between transponder 2 and the receiving antenna 4. Since the signal strength decreases with the third power of the distance, the signal strength of transponder 4 will be much smaller than that of transponder 3 The orientation of the transponders also plays a role, of course. The projection of the transponder plane onto the receiving antenna plane must be taken into account, which makes the strength differences even greater in the example of Figure 2.

With a second receiving antenna 5, the situation arises here that transponder 4 is received much more strongly.

Claims (10)

1. Identification system whereby several transponders of a conventional embodiment can be read simultaneously, characterized in that in the receiver use is made of differences in strength of the signals of the transponders, in order to be able to distinguish them from each other. Identification system according to claim 1, characterized in that the received strength differences of the transponder signals are emphasized by using a very small receiving antenna. Identification system according to claim 1 or 2, characterized in that two or more receiving antennas are used to realize even greater differences in the strength of the transponder signals as they are received. Identification system according to one or more of the preceding claims, characterized in that the strongest signal is first determined, after which the associated code and then its contribution to the received signal can be determined, and this contribution is minimized, after which a weaker transpon -dercode, if any, is determined. Identification system according to claim 4, characterized in that minimizing the contribution of the strong signal is achieved by minimizing the correlation between the incoming signal and the detected signal. Identification system according to claim 4 or 5, characterized in that the received signals from multiple receivers are used to recover the transponder signals. Identification system according to claim 1, 2 or 3, characterized in that one or more small receiving antennas are partly overlapping with the transmitting antenna. Identification system according to one of the preceding claims, characterized in that the antenna coils are arranged in two planes on either side of a passage. Identification system according to claim 3, 4 or 5, characterized in that the relative strengths of the signals on the different antennas are used for determining the position of the transponders. Identification system according to claim 9, characterized in that a neural network calculates the position of the transponders from the received signals.