DE102014105239B4 - Reader for an RFID test system - Google Patents

Abstract

Reader (10) for a test system (1) for checking the presence of at least one object (3) by means of RFID, for interacting with a transponder (5) associated with the object (3), with at least one resonant circuit (12) connected to the Transponder (5) comes into resonance in spatial proximity, and an evaluation device (28) which detects the identifier of the transponder (5), characterized in that the resonant circuit (12) comprises a measuring resistor (18) for measuring the current in the resonant circuit (12 ), wherein the evaluation device (28) picks up a signal at the measuring resistor (18), and that the oscillating circuit (12) for driving a first diode (14), which with its anode with the interposition of a first switch (A) to a supply voltage ( V +) is connected, and a second diode (16) which is connected to its cathode with the interposition of a second switch (B) to ground (GND).

Description

The invention relates to a reading device with the features of the preamble of claim 1.

A reader of this kind is for example from the DE 38 13 779 A1 known. The reader is installed in a playing field, the transponders in the game pieces whose presence is to be checked on the possible positions of the playing field. At each position of the playing field, a resonant circuit is provided whose potential is tapped between coil and capacitor. By means of a spectral comparison with a reference resonant circuit, the resonant frequency is determined, which is individual for each game character and each position of the playing field.

The DE 103 31 059 A1 discloses a transceiver for a vehicle anti-theft device whose resonant circuit interacts with a transponder by means of its coil in the case of spatial proximity. The resonant circuit has two switches with freewheeling diodes for driving and can be quickly de-energized by a special circuit. In the DE 60 2004 002 657 T2 a passive keyless access device is described, the resonant circuit is controlled by means of two half-bridge circuits.

The 60 2004 011 248 T2 shows an electronic educational game set with a game board, a card reader and a dice box. The elements, such as game pieces and game pieces, are provided with RFID tags, which are detected by means of multiple readers. One in the DE 10 2006 009 451 A1 disclosed interaction device for a game board has at several positions of the game board coil units which interact with transponders in the game characters. According to the DE 42 07 534 A1 the sensors are controlled at the individual positions of the game board by means of a respective multiplexer for columns and lines. Finally, the combined US 5,853,327 A a game board, three-dimensional game characters with transponders and audiovisual responses to the movements of the characters. To query the positions on the game board, the game board is divided into cells, each with a coil, the coils are controlled by multiplexers.

The invention is based on the object to improve a reader of the type mentioned. This object is achieved by a reader with the features of claim 1. Advantageous embodiments are the subject of the dependent claims.

Although the measurement of the current in the resonant circuit instead of the voltage (potential) requires to install the measuring resistor in the resonant circuit, has the advantage that the measured variable is more stable. In addition, the same measuring resistor can be used together for several resonant circuits. The resonance frequency is the same for all positions, since the identifier of the transponder is contained in an amplitude modulation of the signal. The control of the resonant circuit by means of diode circuits, which selectively stimulate the selected resonant circuits with a series of pulses. The selection of the resonant circuits is preferably carried out by multiplexers.

In the following the invention with reference to an embodiment shown in the drawing is explained in more detail. Show it

1 a resonant circuit as the core of the reader,

2 a series of pulses at the switches,

3 a plurality of oscillating circuits,

4 a first diode assembly,

5 a second diode assembly,

6 a block diagram of the reader,

7 a schematic representation of the operation of the evaluation,

8th a use as a game,

9 a use in a storage system, and

10 a use for monitoring a closed state.

An electronic test system 1 is used to check the presence of objects 3 in different positions. The test system 1 works with the RFID method, ie non-contact and using radio waves for energy and information transmission. For every object 3 whose presence is to be checked, the test system 1 a transponder 5 on which the object 3 are assigned, in particular attached to or in this. Furthermore, the testing system 1 a reader 10 on which with the transponder 5 interacts and the presence of the transponder 5 can query, thereby indicating the presence of the object 3 close.

The counterpart to the transponder 5 is in the reader 10 a resonant circuit 12 with a coil L and a capacitor C, as well as its driving in 1 is shown. The order of coil L and capacitor C can be changed be. A first voltage divider between a supply voltage V + and the ground GND consists of a first switch A and a first resistor 13 (For example, about 2 to 3 kΩ). Between the first switch A and the first resistor 13 is a first diode 14 connected to its anode, the cathode of the first diode 14 at the resonant circuit 12 connected. A second voltage divider between the supply voltage V + and the ground GND consists of a second resistor 15 (Which is preferably the first resistor 13 is equal) and a switch B. Between the second resistor 15 and the second switch B is a second diode 16 connected to its cathode, the anode of the second diode 16 at the resonant circuit 12 is connected, and at the same potential as the cathode of the first diode 14 , Finally, the resonant circuit points 12 another measuring resistor 18 (For example, about 50 to 100 Ω), which is on the one hand with coil L and capacitor C in series and on the other hand connected to the ground GND.

If the switch A is closed for a short time, this corresponds to a positive pulse on the resonant circuit 12 , The current flows from the supply voltage V + through the closed first switch A, the first diode 14 , the coil L, the capacitor C and the measuring resistor 18 to ground GND. At this time, the capacitor C is charged. By means of the first resistor 13 is the resonant circuit 12 closed. The current in the resonant circuit 12 can be as voltage on the measuring resistor 18 be tapped. If the switch B is closed for a short time, this corresponds to a negative pulse on the resonant circuit 12 , The current flows (in the opposite direction as before) through the second diode 16 , the closed second switch B, the ground GND, the measuring resistor 18 , the capacitor C and the coil L back to the second diode 16 , In this case, the capacitor C is discharged. The current in the resonant circuit 12 can be as voltage on the measuring resistor 18 be tapped.

The switches A and B are preferably formed in a conventional manner as a transistor circuit. Preferably, the switches A and B are alternately closed with a series of positive and negative pulses, respectively, as in FIG 2 shown. The positive pulses for the first switch A and the negative pulses for the second switch B must be offset in time by a sufficiently large time interval ΔP (for example 100 ns) (because otherwise via the two switches A and B and the two diodes 14 and 16 a short circuit occurs).

The transponder 5 is passively trained. At a (immediate) spatial proximity of the transponder 5 to the resonant circuit 12 , more precisely to the coil L, come the resonant circuit 12 and the transponder 5 in a conventional manner in resonance. There is a vibration in the transponder 5 energized, so energy from the resonant circuit 12 on the transponder 5 transmit, so that then the information of the transponder 5 read out and on the resonant circuit 12 can be transferred. Components of the transponder 5 are a coil and a chip connected to both ends of the coil. A capacitor for forming a transponder resonant circuit together with the coil is integrated into the chip or formed separately and connected in parallel to the chip. The chip contains the information that is on the resonant circuit 12 is transferable. The information is preferably an identifier from a predefined value table which contains the transponder 5 clearly identified. If the described resonance occurs between the resonant circuit 12 and transponders 5 on, so the current experiences at the measuring resistor 18 a clear and for the identifier of the transponder 5 unique amplitude modulation, which is measured as described later in more detail.

In the reader 10 is the above-described resonant circuit 12 present in a plurality. For every position to which an object 3 can be present is such a resonant circuit 12 with capacitor C, coil L and first diode 14 and second diode 16 available. Several first diodes 14 may be connected to a common first voltage divider of first switch A and first resistor 13 be connected, as well as several second diodes 16 to a second voltage divider of second switch B and second resistor 15 , The measuring resistor 18 can for all resonant circuits 12 to be together.

In 3 is such a plurality of oscillating circuits 12 by way of example in a checkerboard-like arrangement 20 and shown schematically. The lines of the checkered arrangement 20 is a first multiplexer 21 assigned to the columns a second multiplexer 22 , The first multiplexer 21 supplies eight first voltage dividers from first switch A and first resistor 13 , Eight first diodes 14 are with their anodes to a first diode assembly 25 joined together ( 4 ) associated with one of the first voltage dividers and between first switch A and first resistor 13 connected. The first diode assembly 25 is a line of the checkered arrangement 20 assigned. Each of the first diodes 14 the first diode assembly is a cell of the checkered arrangement 20 assigned.

The second multiplexer 22 supplies eight second voltage dividers from second resistor 15 and second switch B. Eight second diodes 16 are with their cathodes to a second diode assembly 26 joined together ( 5 ) associated with one of the second voltage dividers and between second resistor 15 and second switch B is connected. The second diode assembly 26 is a column of the checkered arrangement 20 assigned. Each of the second diodes 16 the second diode assembly 26 is a cell of the checkered arrangement 20 assigned. For measuring the current through the common measuring resistor 18 will be the on the measuring resistor 18 decreasing voltage by means of an evaluation 28 tapped.

A block diagram of the reader 10 is in 6 represented, again exemplary in the checkerboard-like arrangement 20 , From a carrier frequency f ₀ , preferably in the long wave range, for example, the normalized frequency of 125 kHz, generates the first multiplexer 21 the series of positive pulses (positive half wave), the second multiplexer 22 the series of negative pulses (negative half wave). The time interval ΔP between the pulse edges is generated by suitable RC elements. With a predetermined clock signal, preferably with a clock frequency f _D in the range of about 2 kHz, counts a counter 31 the possible identifiers for the transponder 5 high and gives it to the first multiplexer 21 , The ratio between carrier frequency f ₀ and clock frequency f _D corresponds to the number of possible identifiers for the transponder 5 So for example here 64 ,

The first multiplexer 21 asks the lines of the checkerboard arrangement assigned to him 20 with the counter 31 given possible identifiers for the transponder 5 ie he speaks individually the first diode modules 25 (which are each assigned to a row). The second multiplexer 22 asks the columns of the checkerboard arrangement assigned to him 20 that is, he speaks individually the second diode assemblies 26 (which are each assigned to a column). When the object 3 with the transponder 5 at the requested position of the checkered arrangement 20 is located (ie at the intersection of row and column), this shows at the measuring resistor 18 tapped voltage signal the case of resonance.

This type of query is energy efficient, since at most those of the first multiplexer 21 addressed line is energized, in the present case so only eight capacitors C are loaded, unless they are still loaded from the last query, and there in the second multiplexer 22 queried column is discharged at most at the intersection of line and column, in the present case only a capacitor C and only if the transponder 5 located at the requested position.

The evaluation device 28 has, for example, a demodulator 28a , an analog-to-digital converter 28b and a microprocessor 28c on, wherein several components can be combined in unified circuits, such as the demodulator 28a and the analog-to-digital converter 28b in an (RFID) tag reader (base station). The functioning of the evaluation device 28 is schematic in 7 shown. The demodulator 28a forms from the on the measuring resistor 18 tapped voltage signal, the spectrum and filters this spectrum in the resonant frequency, ie the carrier frequency f ₀ . From the filtered-out signal, which corresponds to the amplitude modulation of the voltage signal, generates the analog-to-digital converter 28b a digital signal, which is the identifier of the transponder 5 equals (or a zero). The one with the counter 31 connected microprocessor 28c can this identifier of the transponder 5 recognize and a corresponding output of the reader 10 make.

A possible use of the test system 1 with a reader 10 with a checkerboard arrangement 20 would be a game, for example chess or lady. The objects 3 are the pawns, each with a built-in transponder 5 exhibit. The reader 10 recognizes at which position which character stands. For example, a chess program may suggest the next move. The reader 10 Can also be used for other game, especially board games, in which a computer is playing and therefore the position of game characters must be recognized.

Another possible use of the test system 1 would be a storage system, for example in the pharmaceutical sector. Every resonant circuit 12 For example, it is integrated into a measuring head, which is connected to a central part of the reader by means of a measuring line 10 connected is. Such a measuring head queries, for example, a certain position in a drawer for medicine boxes, for example, the penultimate position at which a transponder 5 is appropriate. If the penultimate box of medications (which the object 3 corresponds), the reader can 10 trigger a warning or a repeat order.

Yet another possible use of the test system 1 would be the monitoring of a closed state, such as switches on a machine. Again, every resonant circuit 12 be integrated into a measuring head, which by means of a measuring line with a central part of the reader 10 connected is. The as object 3 treated switches carry a transponder 5 , The measuring head queries, for example, whether the switch is open (transponder 5 spaced from the measuring head) or closed (transponder 5 at the measuring head).

In the exemplary embodiment, the first multiplexer 21 all possible identifiers are queried one after the other. But it is also possible to query a specific identifier. The reader searches accordingly 10 after this (on the first multiplexer 21 given) identifier. The result is faster then.

LIST OF REFERENCE NUMBERS

1

retrieval system

3

object

5

transponder

10

reader

12

resonant circuit

13

first resistance

14

first diode

15

second resistance

16

second diode

18

measuring resistor

20

checkered arrangement

21

first multiplexer

22

second multiplexer

25

first diode module

26

second diode assembly

28

evaluation

28a

demodulator

28b

Analog to digital converter

28c

microprocessor

31

counter

A

first switch

B

second switch

C

capacitor

f ₀

carrier frequency

f _D

clock speed

GND

Dimensions

L

Kitchen sink

.DELTA.P

time interval

V +

supply voltage

Claims (9)

Reader ( 10 ) for a test system ( 1 ) for checking the presence of at least one object ( 3 ) by means of RFID, for interaction with an object ( 3 ) associated transponder ( 5 ), with at least one resonant circuit ( 12 ), which with the transponder ( 5 ) comes in resonance in spatial proximity, and an evaluation ( 28 ), which identifies the identifier of the transponder ( 5 ), characterized in that the resonant circuit ( 12 ) a measuring resistor ( 18 ) for measuring the current in the resonant circuit ( 12 ), wherein the evaluation device ( 28 ) a signal at the measuring resistor ( 18 ) and that the resonant circuit ( 12 ) for driving a first diode ( 14 ), which is connected with its anode with the interposition of a first switch (A) to a supply voltage (V +), and a second diode ( 16 ), which is connected to its cathode with the interposition of a second switch (B) to ground (GND). Reader according to claim 1, characterized by a first resistor ( 13 ), which also to the anode of the first diode ( 14 ) is connected and with the first switch (A) forms a first voltage divider between supply voltage (V +) and ground (GND), and by a second resistor ( 15 ), which also to the cathode of the second diode ( 16 ) is connected and with the second switch (B) forms a second voltage divider between supply voltage (V +) and ground (GND). Reader according to one of the preceding claims, characterized in that the first switch (A) with a series of positive pulses and the second switch (B) with a series of negative pulses alternately with a carrier frequency (f ₀ ) is closed, wherein the pulses by a time interval (ΔP) are offset in time. Reader according to one of the preceding claims, characterized in that a plurality of resonant circuits ( 12 ) whose first diodes ( 14 ) with their anodes to a first diode assembly ( 25 ) are connected together and connected to a common first switch (A). Reader according to one of the preceding claims, characterized in that a plurality of resonant circuits ( 12 ) are provided, whose second diodes ( 16 ) with their cathodes to a second diode assembly ( 26 ) and connected to a common second switch (B). Reader according to claim 4 and 5, characterized in that a first multiplexer ( 21 ) the first switches (A) and a second multiplexer ( 22 ) the second switch (B) closes. Reader according to claim 6, characterized in that a counter ( 31 ) the possible identifiers for the transponder ( 5 ) with a clock frequency (f _D ) and successively to the first multiplexer ( 21 ) or that the reader ( 10 ) queries a given identifier. Reader according to claim 6 or 7, characterized in that the first multiplexer ( 21 ) the first diode assemblies ( 25 ) individually, and that the second multiplexer ( 22 ) the second diode assemblies ( 26 ) individually so that at most the addressed oscillating circuits ( 12 ) are loaded or unloaded. Reader according to one of the preceding claims, characterized in that the evaluation device ( 28 ) for the evaluation of the measuring resistor ( 18 ) tapped signal one Demodulator 28a ) for demodulating, an analog-to-digital converter ( 28b ) for digitizing and a microprocessor ( 28c ) for recognizing the identifier of the transponder ( 5 ) having.

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