NL8802718A - Consecutive read=out system for multiple RF detection labels - uses transceiver, with group of labels switched on or off vby algorithmic selection procedure - Google Patents

Abstract

The wireless detection system comprises a transceiving part which transmits a r.f. field. The batteryless detection labels, each with its own unique code, are situated in this field simultaneously and can be read one by one. Each time a group comprising one or more detection labels is switched off using an algorithmic selection procedure. This selection procedure selects two possible bit values from which the code signals of the various detection labels are constructed. The selection procedure of the various detection labels is started after the synchronisation of the various labels, which is effected by a code from the transceiver. @(6pp Dwg.No0/0).

Description

Nedap N.V.

Sequentially reading multiple radio frequency detection labels in one interrogation field

The invention relates to a wireless detection system, consisting of a transceiver section that emits a radio frequency field and a plurality of battery-less detection labels, which can be located simultaneously within this field and of which the code, unique for each label, can be read one by one and can be decoded by the receiver section.

In applicant's Dutch patent 176404, a wireless detection system is described, in which a battery-less (a so-called passive) electronic detection label is activated by placing it within the interrogation field of a transceiver, which field consists of a continuous radio frequency unmodulated carrier golf exists. In this process, the label absorbs energy from the interrogation field, which is then used to power a built-in electronics circuit. This circuit mainly consists of a receiver coil, which forms a resonant circuit with a capacitor, resonating at the carrier frequency of the interrogation field, a memory circuit and an encoding circuit.

The memory circuit contains the unique number of the detection label. This is read out by the coding circuit, which rhythmically short-circuits the receive circuit according to the desired code pattern. Thus, the code pattern is converted into an attenuation difference pattern, which can be detected by the receive portion of the transceiver, so that the code can be recovered. This system is widely used, but has the drawback for some applications that detection is impossible when multiple detection labels are simultaneously in the interrogation field.

The object of the invention is to solve this problem and thus enable the separate reading of several labels that are simultaneously in the interrogation field.

Use is made of a signal transmitted with the interrogation carrier, which allows only one or a group of the detection labels to be read to respond with their code (s).

By using an algorithmic selection procedure, the codes of all detection tags simultaneously within the interrogation field can be retrieved successively. To this end, the following principle is used. Each detection label produces a signal formed by rhythmically short-circuiting the resonant circuit. Whenever the resonant circuit is not shorted, energy is absorbed from the transceiver. This periodic loading of the carrier signal of the transceiver can be implemented as a code. This code can be compiled digitally as follows. The block signal of the detection label always shows the variation in the load. Each period can be designated as a bit, with a certain value. In the period that the transmission energy is absorbed, this bit is, for example, given the value 0. In the period when the resonant circuit is shorted, no absorption takes place and, for example, the bit is given the value 1. The code can then be composed of a certain number of bits with corresponding values. This code is still checked for integrity by a so-called checksum and / or parity check. If this checksum is correct, it is established that there is only one detection label in the interrogation field.

As mentioned earlier, if several detection labels are present in the interrogation field, the transceiver cannot distinguish between the periodic loads of the carrier wave, which differ per detection label, because the checksum and / or the different detection labels are determined as incorrect.

The principle of the invention is based on comparing the signals of the different detection labels. The scheme of equations takes the form of a tree structure. After the received signals are compared, each detection tag is selectively disabled.

If it is assumed that each period during which absorption by a detection label takes place, the relevant bit is assigned a value of 0, one or more detection labels of which the bit value is 0 can be grouped per bit. For example, if the first bit has a value of 0, absorption takes place and the relevant detection label (s) is or are activated.

If detection labels are detected in the interrogation field where the bit value is 0, these detection labels are deactivated. Only the detection labels with the first bit value 1 are admitted to the next selection procedure. In this second selection, which takes place at the second bit, it is checked again whether there are detection labels with the bit value 0. If, in this selection on the second bit, there are activated detection labels with thus bit value 0, they are also deactivated. Any other detection labels undergo the third selection procedure on the third bit. Here, too, the detection labels with bit value 0 are deactivated, and the other detection labels with bit value 1 continue to the next selection procedure until one detection label remains. This last detection label can then be detected,

The next selection is made by jumping back to the penultimate selection procedure. In this selection procedure, a group, consisting of one or more detection labels, has already been deactivated with respect to the only remaining detection label with bit value 0. The deactivated group of detection labels is selected via a different branch of the tree structure each time during the selection on the next bit. the values 0 and 1.

The groupwise distribution of active and non-active detection labels leads to ever larger groups of deactivated detection labels. In this way, all detection labels are identified along a tree structure, the identification not taking place by comparing the codes, but by each time creating an ever smaller subset of possible codes of still active detection labels, so that ultimately a subset of possible codes is created in which there is only one detection tag left. It is then no longer necessary to look further in this remaining subset, which considerably speeds up the selection.

A second acceleration of the selection process is achieved by not looking in subsets of possible codes of which no detection labels are present in the transmission field, but only by looking for the identity of the detection labels or groups of detection labels known to the transceiver.

Deactivation of the detection labels remaining from the previous procedure is effected by having the transceiver, via frequency modulation, form a code different for each bit, so that all detection labels with bit value 0 at the bit position corresponding to this code are switched off and therefore temporarily switched off. the selection process must be met. This group of disabled detection labels is later brought back into the selection process, also via a code formed by the transceiver.

Like the codes for enabling and disabling detection tags, the transceiver generates a synchronization signal. The synchronization signal serves to synchronize the detection labels which are located in the interrogation field. The synchronization of the start of the code signals ensures that each code of each detection label can be checked for the value 0 in a series of bits. Here too, for example, the synchronization signal may consist of the frequency modulation of the transmitter, which modulation can be recognized by the detection label.

By varying the frequency between two predetermined values, a code pattern can be formed, thus enabling the detection tag to be switched in multiple modes. A code is created for each mode. For example, the code for turning on and off can be immediately followed by the bit number in the respective bit sequence. Each selection in the process then refers to a specific bit number in a bit sequence. As a result, at each selection point, i.e. at every bit in a bit sequence, a certain group of detection labels can be switched on or off.

Three situations can arise in the questioning field. In the first case, no detection label is present in the interrogation field. In the second situation, one detection label is located in the interrogation field, which can be determined on the basis of, for example, checksum and parity bits in the code. In the latter case, several detection labels are located in the interrogation field. The checksum and parity bits are incorrect if several detection labels are present in the interrogation field, whereby the selection process according to the invention is started.

Claims (7)

A wireless operating detection system, consisting of a transceiver section that emits a radio frequency field, characterized in that several battery-free detection labels, each with its own unique code, which are simultaneously located within this field, can be read one by one, each time by means of a group consisting of one or more detection labels, is temporarily switched off via an algorithmic selection procedure, which procedure selects on two possible bit values from which the code signals of the various detection labels are built. A wireless operating detection system according to the preceding claim, characterized in that the selection procedure of the various detection labels is started after synchronization of the various detection labels, wherein the synchronization is effected by means of a code from the transceiver. A wireless operating detection system according to one or more of the preceding claims, characterized in that the various detection labels in an interrogation field receive codes, which are transmitted from the transceiver, and which indicate on the one hand whether the detection label should switch on or off and on the other hand, depending on the content of which bit position of the code of the detection label, this switch must take place. A wireless detection system according to one or more of the preceding claims, characterized in that the synchronization code and switch-on and switch-off codes are transmitted from the transceiver to the detection label by modulating the frequency of the transceiver and wherein the detection label is transmitted via a demodulator is able to recover these codes from the signal. A wireless detection system according to one or more of the preceding claims, characterized in that detection labels that make insufficient magnetic coupling or otherwise do not send a normally repeating code can be switched off by the transceiver and brought into the selection process later by synchronization of the relevant detection labels. A wireless operating detection system according to one or more of the preceding claims, characterized in that the selection procedure selects only on the detection labels activated during the selection and therefore with a bit value 0 on the bit position of the code of the detection label referred to in the present selection. A wireless operating detection system according to one or more of the preceding claims, characterized in that the algorithmic selection procedure, unlike known binary selection procedures, only selects on detection labels known in the transmission field and does not select further if only one unique detection label number is used in the present subset recognized, significantly speeding up the selection process.