CS245759B2 - Detection plate for electromagnetic identification system - Google Patents

Abstract

The wiring relates to a detection plate for electromagnetic identification system equipped with a resistor circuit, switching member and coding means. The essence the circuit is that the coding circuit is executed as a digital circuit, its · first and the second power input is connected to the resonant by a circuit through a rectifier member, its control input is connected to the resonant circuit and its output is connected to resonant circuit through a switching actuator. Detection the plate is suitable for identification persons, goods or animals passing through the screen zone.

Description

The invention relates to a detection plate for an electromagnetic identification system provided with a resonant circuit, a switching element and coding means.

Such systems are already known and can be used, for example, when certain rooms in a building are accessible only to a predetermined group of persons, or when goods are automatically delivered and / or registered in a large warehouse. Persons, goods or animals carry an identification plate, in which the electrical circuit is responsive to the electromagnetic field generated in the detection zone and outputs a signal or at least the size of ^one of the electromagnetic field influences, which can be detected by the appropriate means.

When using the signal generated by the detection plate and retransmitted, there are in addition to the transmission means reception means which receive the retransmitted signal and can process it into a detection signal. Conversely, if the fact that the detection plate affects the generated electromagnetic field is generated, only the transmitting means and the organs associated with the transmitting means are required to detect the change in the electrical load of the transmitting means associated with the presence of the detection plate and can process the change into signal.

The electrical circuit located in the detection plates for the identification system is designed to generate an encoded detection signal, the coding of which depends on the class to which the detection plate or the persons, animals or goods carrying the detection plate belong.

The encoded detection plate for the identification system is already described in U.S. Patent No. 3,299,424. This known detection plate comprises a resonant circuit that can be periodically tuned by a switching member by a code frequency determined by the circuitry in the detection plate. The disadvantage of this coded detection plate is, however, that in order to achieve a convenient switching effect or coding, the known detection plate has to be provided with a battery power supply which must be replaced after a certain period of time and often has a lower terminal voltage. which can lead to incorrect coding and incorrect detection.

In the detection plate according to the invention, these disadvantages are overcome by the coding circuit being a digital circuit, the first and second power input being connected to the resonant circuit via a rectifier member, the control input of the coding circuit being connected to the resonant circuit and its output it is connected to the resonant circuit via a switching member. In a preferred embodiment, the control input of the coding circuit is coupled to the resonant circuit via an-oscillator. In another preferred embodiment, the coding circuit comprises a counter whose outputs are connected to the control inputs of at least one multiplexer circuit comprising adjustable coding inputs, the output of the multiplexer circuit being coupled to the switching member. In a further preferred embodiment, the first to third and fifth outputs of the counter are coupled to the control inputs of the at least one multiplexer circuit and its fourth output is coupled to the coding inputs of the at least one multiplexer circuit. In yet another preferred embodiment, the fifth counter output is coupled directly to the fourth control input of the first multiplexer circuit and to the fourth control input of the second multiplexer circuit via a second inverting product gate.

The advantage of the detection plate according to the invention lies in tolm. This means that it does not need a battery and thus ensures long-term trouble-free operation with minimal maintenance, while maintaining the advantage of a small footprint due to the use of only one LC circuit.

An exemplary embodiment of a detection plate according to the invention is shown in the accompanying drawings, in which FIGS. 1 and 2 show a one-dimensional embodiment of a detection plate according to the invention in two variants; FIG. and Fig. 4 shows the waveforms of the wiring of Fig. 2 in operation.

Giant. 1 shows a detection plate in which there is a resonant circuit consisting of a parallel connection of a coil Lr and a capacitor Cr, the resonance frequency of which corresponds to the frequency of the electromagnetic detection field in the detection zone. The resonant obtoid tr, Cr is coupled by its first output to the first input of the rectifier SP, to the first terminal of the switching member S and via a resistor R to the input CL of the coding circuit TC and its second output to the second input of the rectifier SP. The third terminal of the switching member S is coupled to the output CS of the coding -o-point-TC TC. The first and second supply inputs CA and CB of the coding circuit TC are connected respectively to the first and second outputs of the rectifier member SP ·

FIG. 2 shows another variant of a detection plate according to the invention where the output of the oscillator OS is connected to the input CL of the coding circuit TC instead of the resistor R, the inputs of which are individually connected to the first and second outputs of the rectifier member SP.

On o-br. 3 shows a more detailed circuit diagram of an exemplary embodiment of a coding pad according to the invention. Here the coding circuit TC comprises a counter T whose outputs A, B, C are individually connected to the control inputs Sal, Sel, Sbl of the first multiplexer circuit 20 and the control inputs Sa2, Sb2, Sc2 of the second multiplexer o-bvo245759 du 21. The fourth output D of the counter T is coupled to the coding inputs C11 of the first multiplexer circuit 20 and the coding inputs C12 of the second multiplexer circuit 21. The fifth output E of the counter T is coupled to the fourth input Sel of the first multiplexer circuit 20 and The output terminal u1 and u2 of the first and second multiplexer circuits 20 and 21 is connected to the output CS of the coding circuit TC via the first inverting product gate 23. The switching member S is formed by the connection of transistor 25 and the rectifying member SP is formed by the conventional connection of the first and second diodes D1 and D2 and the first and second capacitors C1 and C2. The oscillator OS is formed by a common circuit of the product gates.

In operation, the detection plate is introduced into the detection zone, and thus the resonance circuit Lr, Cr is brought into the resonance by the detection field: This creates an alternating voltage in the resonance circuit Lr, Cr.

The rectifying member SP converts this AC voltage into a DC supply voltage and this is applied to the citation and TC coding circuit, which is an integrated circuit. Also, the DC-powered oscillator OS supplies knock pulses to the counter input CL of the TC coding circuit. Stepping pulses can also be obtained using the second wiring variant of FIG. 2 by applying the AC voltage generated at the resonant circuit Lr, Cr via the resistor R at the counter CL of the counting and coding circuit TC. The AC voltage peaks may be used as sequential pulses for the counting portion of the counting and coding circuit TC.

The sn section counter has 2 ⁿ possible output combinations. Therefore, a single 10-segment counter already has 1,024 different output states. By means of the coding part of the counting and coding circuit TC, a code signal can now be generated which is characteristic of a specific detection plate or a certain group of detection plates and which corresponds to one of the possible output states of the counter. This characteristic code signal is used by the switching member S to periodically tune the resonant circuit Lr, Cr or even to short-circuit it in rhythm, by determining the coding part of the coding circuit TC.

The tuning of the resonant circuit Lr, Cr can be performed by periodically paralleling an additional capacitor to the capacitor Cr or by periodically shorting a part of the coil Lr. It is also possible to use a code signal to periodically connect a non-linear element to the circuit or to modulate the oscillator signal of the OS.

Now that the detection plate of the described type is in the detection field, periodic attenuation and / or damping occurs in the rhythm determined by the TC coding circuit, resulting in periodic attenuation of the signal retransmitted by the detection plate, which can be easily detected, or which can also be detected. The specific rhythm of attenuation or ¹ change in absorption allows identification of persons, goods or animals.

A separate oscillator OS, which oscillates as soon as the supply voltage supplied by the resonant circuit Lr, Cr reaches a given value, is accommodated in the circuit of FIGS. 2 and 3. The oscillator OS is assembled in a known manner from two product inverting gates and several resistors and capacitors. The advantage of using a separate oscillator OS that supplies counting pulses for the digital counter T is that the oscillator oscillator frequency is very stable and independent of external disturbances. The pulses of the standalone oscillator OS are applied to the counter input CL of the digital counter T formed by the integrated circuit and receiving the supply voltage from the resonant circuit Lr, Cr. The digital counter T has five outputs A, B, C, D and E, which in the illustrated embodiment are connected to two integrated, digital multiplexer circuits 20 and 21. The digital multiplexer sub-circuits 20 and 21 have several control inputs Sal, Sbl, Sel and Sel, optionally Sa2, Sb2, Sc2 and Se2. Furthermore, the digital multiplexer circuits 20 and 21 have a number of coding inputs C1i or C1z, respectively. The signals supplied to the control inputs Sal, Sb1, Sel and Sel, respectively Sa2, Sb2, Sc2 and Se2 determine which coding inputs are to be connected to the output terminals u1 and / or U2. Thus, the number of possible coding could be increased by using a third multiplex circuit.

Giant. 4 shows several waveforms occurring in the circuit according to FIG. 2. The signals A, B and C occurring at the outputs A, B, C of the digital counter T are applied to the control inputs Sal, Sbl, Sel or Sa2, Sb2 and Sc2 of the digital multiplexer circuits 20 and 21. The output signals D and E of the digital counter T play a particular role. The signal D is applied to the coding input C1 or C1 of the digital multiplexing circuits 20 and 21. Thus, it is achieved that only the coded signal is transmitted during certain time intervals, in this case when the signal D is at the L-level. The impact of this measure will be shown in the following.

The signal E is applied to the fourth input Sel of the first digital multiplex ¹ circuit 20 directly and inverted through the second inverting product gate 22 to the fourth input Se2 of the second digital multiplex circuit 21. Thus, when the signal E is level H, it transmits the first digital a multiplex circuit 20 with the ^code: gnál and that when the signal E is L level, it sends a second digital multiplex circuit 21 of the code signal.

The output signals of the digital multiplex sub-circuit 20 and 21 are applied via a first inverting product circuit 23 to a switching member S. The switching member S consists essentially of a transistor 25 which can be brought into a conductive or closed state by means of code signals. An example of a signal applied * through the first inverting product gate * 23 is shown in Fig. 4 as a signal F. Reference numerals I and II denote the intervals at which the coding originates from the digital multiplexing band 21 or 20, respectively.

The base of transistor 25 is controlled via the inverted signal F via a series resistor and a parallel capacitor. When the transistor 25 is in a conductive state, the resonant circuit Lr, Cr is shorted in this embodiment, so this is an extreme way of tuning the resonant circuit Lr, Cr. The signal G generated by the resonant circuit Lr, Cr is shown in FIG. 4.

Since the resonant circuit Lr, Cr not only produces the coded signal, but also supplies the supply voltage for the coding means, the resonant circuit Lr, Cr cannot remain shorted for too long. This is the reason for the previously described processing of signal D, which causes so-called power transmission blocks 30 in signal G. to be formed. These power transmission blocks 30 may further be used to be on the detection side of the system, which may lie on both the transmission side, also on the separate receiving side of the system, it generated a synchronization signal. The synchronization signal may be converted to a clock signal which, when synchronized with the code signal, introduces the code signal into the shift register. In this way, a suitable indication of the defects of the detection plate signal can be obtained.

There are other possibilities for transmitting the signal between the detection plate and the decoding device in addition to periodically shorting the entire resonant circuit.

Thus, an auxiliary coil or an auxiliary capacitor can be connected to the resonant circuit Lr, Cr or by means of a transistor 25 as a switch. Furthermore, it is possible to connect a transistor 25 as a switch periodically to a resonance circuit Lr, Cr of a non-linear element, such as a diode. In the first case, the resonance circuit Lr, Cr coded is tuned, in the second case the resonance circuit Lr, Cr is coded at least one third frequency, based on two transmission frequencies.

The detection plate described can be used both in an identification system with a transmitting device serving simultaneously as a receiving device, as well as in an identifying system with a transmitting device and a receiving device.

Various modifications to the disclosed detection plates are readily apparent to those skilled in the art. It is essential that the detector plate generates its own counter pulses, from which a code is formed which consists of power transmission blocks and coded blocks, wherein the power transmission blocks are used to recover the synchronized signal on the detection side, for example by means of a phase loop. This achieves an almost insensitive coding in the detection plate while detecting the code on the detection side can be done in a reliable manner.

The detection plate is suitable for identifying persons, goods or animals passing through the detection zone.

In practice, such an identification system may find application, for example, for cows in a free stable. There are several feeding troughs in the voile stable that are accessible to all cows in the herd. However, for the proper breeding of cows, each cow must receive a measured quantity of compound feed suitable for that cow. This can be achieved by providing each cow with an encoded detection plate and creating a detection zone for each feed trough. In this way, the cow can be identified in front of the feed trough and the amount and composition of the feed composition can be adapted to the respective cow.

Claims (4)

A detection plate for an electromagnetic identification system having a resonant circuit, a switching member and coding means, characterized in that the coding circuit (TC) is designed as a digital circuit, its first and second supply inputs (CA, CB) being connected to the resonance circuit (Lr, Cr) through the rectifier member (SPJ), the control input (CL) of the coding circuit (TJ is connected to the resonant circuit (Lr, Cr) and its output (CS) is connected to the resonant circuit (Lr, Cr) through the switching member (WITH). Detection plate according to Claim 1, characterized in that the control input (CL) of the inventive circuitry (TC) is connected to the resonant circuit (Lr, Cr) via an oscillator (OS). Detection plate according to Claim 1 or 2, characterized in that the coding circuit (TC) comprises a counter (T) whose outputs (A, B, C, D, E) are connected to the control inputs (Sal, Sbl, Sel , Sel) of at least one * multiplexer circuit (20) provided with adjustable coding inputs (C1i), the output (u1) of said multiplexer circuit (TC) being coupled to a switching member (S). Detection plate according to Claim 1 or 2, characterized in that the first to third and fifth outputs (A, B, C, E) of the counter (T) are connected to the control inputs (Sal, Sbl, Sel, Sel) of at least one the multiplexer bypassing the water (20) and its fourth output (D) together with the coding inputs (C11) of at least one multiplexer circuit (20), 3 sheet of drawings