NL1002807C2 - Electronic transponder detection system - Google Patents

Abstract

When two passive identical transponders pass through a detection field at the same time, conventional detectors cannot interpret the responses correctly as bits of the code from one response can negate bits from the other code. The present system processes the received signal to produce separate output signals. The output (1) of the radio frequency receiver is supplied to a delay circuit, which delays the signal by one cycle of code repetition. The delayed signal is then added to the undelayed signal to produce one code, while the undelayed signal is subtracted from the delayed signal to produce the other code.

Description

Two responders at the same time recognized by PACE (Phase Alternating Code Extension)

For the automatic recognition of animals, a collar with a responder which works according to the field absorption principle is very common. An embodiment of such a responder is described in the Dutch patent no. 176404 of the applicant. These systems have been used for many years in livestock farming. The same principle is also applied in many other industries. A limitation of these systems is often that when several responders are used on an animal, mutual influence can arise at a small distance, so that neither responder can be read.

The system as described in applicant's patent application no. 9300250 can under certain conditions be read by both responders; however, this requires, among other things, a doubling of the number of recipients.

In some applications, a spatial separation can be made. In cattle farming it is usual, for example, to attach a responder to the collar of the animal for identification of the animal, while a responder with built-in pedometer and its own identification code is mounted on a leg of the same animal.

The invention offers a solution to place two responders very close to each other, without interfering with the reading of each of these responders.

It is hereby also possible to arrange a second responder with a built-in sensor at the first, whereby the first responder is still used for identification of the animal, while the second responder only needs the sensor data and thus no identification code. This makes the second responder easier to produce, but also makes it easier to link the sensor data to a certain animal; after all, there is only one and the same animal identification for animals with and without a sensor.

Access control systems with responders are increasingly used to control access to buildings. That only one responder at the same time 100280? It is not a big problem to read two digits here, as the access right is also individually regulated. When applying security techniques to protect expensive properties such as computers against theft, also known as "Asset protection", a common method is to attach an identification label in or to the article to be protected, and a detector at the exit of the building. - place this device for this label. If the person who wants to leave the secured building with such a secured device, a problem arises if this person also carries an access control label with him. The usual solution is that the access and security systems work completely independently, so that in fact two different systems are placed. This of course greatly increases costs.

The invention allows access provision and asset protection to be integrated into one system.

In the usual types of responders, for example as standardized according to ISO ....... it is usual that the code frame is continuously generated by the responder. In said ISO standard, a frame with a length of 128 bits is defined, in which the first bit of the next frame is immediately placed after the last last bit. In the receiver, adding the corresponding bits in two successive frames will only double the value of the actual. Likewise, subtracting the corresponding bits in two consecutive frames will make the signal disappear. For a code 25 according to the ISO standard, this means that the sum signal of bit 1 and bit (1 + 128) doubles, and the difference signal of these bits becomes zero.

By now choosing a signal structure for the second responder, in which the successive frames are not always the same, but alternately in alternating phase, the addition of the corresponding bits is the opposite of the situation outlined above, when adding and subtracting corresponding bits.

This also applies if both responders are active simultaneously. In addition, a signal then arises which is the sum of the two response signals. Without the measure of the invention, an undetectable addition of two code streams now arises.

The invention makes it possible to recover the two responder signals from this addition. If the code frame of the second responder is the same length as that of the first responder, adding the signal to the signal delayed over a frame length will produce the code of the first responder, and upon subtracting, the code of the second 1002807 3 responder. This effect also occurs if the responders are placed very close to each other. The necessary signal operations can be easily performed by a microcomputer. Because the recognition of the two different codes takes twice as long in this new way, the information density has also remained the same, so that the signal-to-noise ratio doubles. The desired receiver bandwidth is no different from that required for the individual codes.

The effect can be obtained in a very simple manner by using a first responder with the said ISO coding, wherein the parity is even, while the second responder has an odd parity. Due to this odd parity, the differential phase shift encoding uses an inversion of the phase of the successive code frame.

13 More generally, it can be stated that if one of the two responders continuously transmits the information of a certain data bit in phase and a little later in reverse phase, while the second responder transmits a data bit of the same phase in the receiver by delaying and addition and subtraction of the signals, both responder codes can be detected. The frame length of the second responder may therefore also be twice that of the first responder; of course the recognition time will be twice as long.

More generally, as long as the frame length of the second responder is a whole number of times the length of the first responder code, the method described will work. Obviously, the recognition time will be proportionately longer.

The invention can also be extended to a system with three responders, in which the third responder must then have an encoding that ensures that the phase is always inverted after two code frames.

In figure 1 the code structure is illustrated in an example.

Figure 2 shows the recovery of the one code by addition. In Figure 3, the recovery of the second code by subtraction is illustrated.

Figure 4 shows the phase changes of a system with two or three 33 responders.

Figure 5 shows a block sketch of the signal processing in the receiver.

An embodiment of the invention will now be described in detail with reference to a code example. Figure 5 indicates that a tape 40 continues to transmit the same code frames continuously without phase inversion. In signal 1, the + symbolically indicates that each frame is transmitted with the same phase. A second responder, indicated by 2 in Figure 5, has a code structure such that the phase of the code is inverted after each frame. The + and - in figure 2 symbolize this.

Details of an exemplary code build-up are schematically shown in Figure 1, with one code 1 continuously repeated in successive frames, while the second code 2 changes with each phase repeat. If both responders are active, a prior art receiver will receive the addition of both codes 10. This addition is indicated by 3 and 4.

By now adding the signals 3 and 4 in the receiver, the original code 1 appears and the responder code 2 disappears. The amplification doubled as a result of the addition. This is shown in figure 2.

The signal 5 generated by adding 3 and 4 has the same form 15 as the original code 1. Figure 3 shows that subtracting two consecutive received codes 3 and 4 yields the code 6. This is again the same form as the original responder code 2.

Extending the system to simultaneously receive three responders is also possible if the third responder has a phase change in the 20 code, as shown in figure 4 in 3. For clarity, the code frame boundaries are drawn synchronously, but this is not important for the proper functioning of the invention. Only the length of the code frames is important, not the mutual phase.

Figure 5 shows a block diagram of the signal processing. This contains a delay block. It is essential that the signal delay time of this block is equal to the length of a code frame, so that the information of the same data bit is at the input and output of this delay block. By adding up the signal with the phase inversion then disappears and responder signal 1 remains; subtraction results in the 30-phase bits being dropped and the signal from responder 2 remaining. Realization of this algorithm can easily be performed analogously by using a bucket of memory and known addition and subtraction circuits.

Another realization is using a microprocessor, where the delay is formed by digitizing samples from the receiver output 1 in Figure 5 with an analog to digital converter and storing the samples in the memory of the microcomputer.

1002807

Claims (5)

1. Recognizing two responders in one interrogation field, characterized in that the code of one of the responders is inverted each frame, while the code of the other responder is the same for each frame, the frames being the same length, so that when adding of 5 received corresponding frames the code of one responder appears and when subtracting the corresponding frames the code of the other responder appears. 2. Recognizing two responders in one interrogation field, characterized in that the code of one of the responders is inverted in each successive frame 10, while the code of the other responder in each frame is the same xb, the ratio of the frame lengths being is an integer, so that when the received corresponding frames are added, the code of one responder appears and when the corresponding frames are subtracted, the code of the other responder appears. 3. Recognizing two or more responders in one interrogation field, characterized in that the code of one responder is continuously inverted after one frame, while the code of a second responder is either twice the length of the code of the first responder or 20 is broadcast twice with the same polarity, after which an inverted version is broadcast again for the same time, which can be repeated with a third and subsequent responder, after which the last responder is finally performed without polarity change. Recognizing two responders in one interrogation field according to claim 1 or 2, characterized in that one responder generates identification data and the other responder generates sensor data. 5. Recognizing two responders in one interrogation field according to claim 1 or 2, characterized in that one responder contains identification data for granting access, while the other responder is used for 'asset protection'. 1002807