DE10045695C1 - Contactless data carrier - Google Patents

Abstract

The invention relates to a contactless data carrier (2) with a coupling element (L1), a first and a second rectifier circuit and a switch (S1), which is connected to a modulator control circuit, for switching between the two rectifier circuits, so that a DC voltage U¶V ¶ is generated by one and / or the other rectifier circuit. In addition, the data carrier (2) has a voltage control circuit (DZ) which is connected to the outputs of both rectifier circuits. The two rectifier circuits represent different loads, so that load modulation is realized by switching from one rectifier circuit to the other.

Description

The invention relates to a contactless data carrier, the is operated passively.

Such a data carrier usually consists of a cop pelelement and from an electronic microchip. except the behavior is within the range of a reader Disk that usually does not have its own power supply gung possesses, completely passive. Only within the response The area of a reader is activated. The energy required to operate the data medium, eventu ell as well as clock and data, by the coupling element kon transferred tactless to the data carrier.

If a resonant data carrier, in which the natural resonance frequency of the data carrier corresponds approximately to the transmission frequency of the reading device, is brought into the alternating magnetic field of the antenna of the reading device, the data carrier withdraws energy from the magnetic field. Via the feed current of the antenna of the reader, this additionally removed energy can be measured as a voltage drop across the internal resistance of the reader. Switching a load resistance on and off on the coupling element of the data carrier causes voltage changes in amount and / or phase on the antenna of the reader and thus corresponds to a modulation of the antenna voltage by the removed data carrier. If you control the switching on and off of the load resistor using data, this data can be transferred from the data carrier to the reader. This form of data transmission is called load modulation. A corresponding arrangement is known, for example, from Klaus Finkenzeller: RFID manual, Karl Hansa Verlag, 2nd edition, Munich 2000 .

An arrangement according to the prior art is shown in FIG. 1. A reader 1 and a contactless data carrier 2 are coupled to one another via a magnetic field H. A coil L11 is provided on the data carrier 2 as a coupling element. Together with a capacitor C11, it forms a resonant circuit. A microchip MC is connected to the coil L11 via a rectifier diode D11. A smoothing capacitor C12 ensures that the ripple of the DC voltage is reduced. It also serves as a backup capacitor. In parallel to the coil L11 there is a switch 13 designed as a transistor, through which the coil L11 can be short-circuited or a load resistor can be connected in parallel. The transistor 13 is driven by a data signal 12 from the microchip MC. As a result, the load modulation described at the outset can be carried out.

The problem with such an arrangement is the voltage supply of the microchip MC, since the capacitor C12 is not recharged when the switch 13 is switched on. Depending on the situation of the data carrier, i.e. the distance from the reading device, the power consumption and the duration of the modulation signal, the voltage supply can drop until the function of the data carrier fails. This is particularly the case when the capacitor C12 is integrated in the microchip MC and its capacity is therefore limited.

From US 5349173 it is for a contactless data carrier known that a diode of a rectifier by means of a MOS transistor is bridged.

Furthermore, DE 198 12 728 A1 is a contactless transfer known transmission system in which as a voltage control circuit a zener diode is used.

The object of the invention is a contactless data carrier to provide, in which the power supply also under difficult conditions is guaranteed.

This task is solved with a contactless data carrier

• - a coupling element,
• - A first and a second rectifier circuit, the have different input resistances and their Inputs connected or connectable to the coupling element  are to obtain a DC voltage from one in the Coupling element generated AC voltage,
• - A changeover switch with a modulator control circuit is connected to switch between the two equals rectifier circuits so that the DC voltage through the one and / or the other rectifier circuit is generated will and
• - A voltage control circuit with outputs of both Rectifier circuits connected or connectable.

In the data carrier according to the invention, the coupling element not short-circuited or the energy in a contradiction stood in heat, but for modulation is on egg ne second rectifier circuit switched. Since this is so is designed to be a different input resistance sits, switches to another rectifier circuit represents a change in load, which in turn is the desired one Corresponds to load modulation. But the advantage is that the energy is not used senselessly, but knows also available for the power supply of the data carrier stands.

The two rectifier scar advantageously have shared components. In one particularly advantageous embodiment of the invention is one of the same judge circuits as voltage multiplying equals judge circuit trained. This will result in different input resistances. At the exit the same the voltage regulator circuit is arranged net, so that an increased voltage in turn on a simple Chen voltage value is reduced. If there is a parallel controller is provided, this can be done with little loss. A Another advantageous embodiment of the invention is in the subclaim 5 specified.

The task is also solved with a contactless data carrier

• - a coupling element,  
• - A rectifier circuit for obtaining a rect voltage from a change generated in the coupling element selspannung,
• - One connected to a modulator control circuit Switch through which an energy store is in a charging phase is connectable to the coupling element, the energy memory represents a load, and
• - A voltage control circuit that works with the rectifier circuit and the energy storage is connected, the energy stored in the energy store in a Ent loading phase into one with the output of the rectifier scarf device connected sink is unloadable.

Since the energy storage with the voltage control circuit ver is bound, can be stored in the energy storage Energy can be used to supply power to the data carrier be made.

The invention is illustrated below with the aid of an embodiment game explained in more detail. It shows:

Fig. 1 is a contactless data carrier according to the prior art,

Fig. 2 is a circuit diagram of a contactless data carrier with a voltage doubler circuit

Fig. 3 is an enlargement of the circuit arrangement of Fig. 2 for switching off the voltage doubling function,

Fig. 4 is a contactless data carrier according to the invention as an extension of the circuit arrangement of Fig. 3,

Fig. 5 is an oscillogram of the data carrier according to the prior art and

Fig. 6 is an oscillogram of the data carrier according to the invention according to Fig. 4.

The arrangement according to the state of the art according to FIG. 1 has already been discussed in the introduction to the description, so that in order to avoid repetitions it is not discussed again here.

In FIG. 2, the rectifier circuit that exists in Fig. 1 only the diode 11, so extended that results in a voltage doubling circuit. In this so-called Villard circuit, a capacitor C3 is connected between a coil L1 serving as a coupling element and a rectifier diode D2, which corresponds to the diode D11 in FIG. 1. The second connection of the coil L1 is connected via a diode D1 to the second connection of the capacitor C3. During the negative half-wave of the induced voltage in the coil L1 is _L1, the capacitor C3 through the diode D1 to the Ampli tude _L1 of the alternating voltage across L1 charged. During the positive half-wave, the diode D1 blocks. Via a smoothing capacitor C2, which is connected to the cathode of the rectifier diode D2 and the second terminal of the coil L1, the supply voltage U _{V is} tapped. During the positive half-wave, the capacitor C2 is charged via the diode D2 to the voltage _L1 + UC3, which means a doubling of _V compared to _L1 . The voltage induced in the coil L1 is therefore superimposed on the direct voltage U _C3 .

In order to be able to use as many components of this second rectifier circuit as possible with a first rectifier circuit, the circuit arrangement according to FIG. 2 should be expanded so that the voltage doubling function can be switched off ( FIG. 3). For this purpose, a third diode D3 is connected between the second connection of the coil L1 and the anode of the diode D1. The anodes of the two diodes D3 and D1 are connected. At the same time with the second connection to the coil L1, a fourth diode D4 is connected, the cathode of which lies on the cathode of the rectifier diode D2. During the negative half-wave, the capacitor C3 can no longer be charged, but a normal bridge rectifier circuit results. The capacitor C3 does not interfere in this arrangement, since no more DC voltage is built up on it.

The switchover between the two rectifier circuits according to the invention is carried out according to FIG. 4 by a switch S1 which bridges the third diode D3 and which is controlled by a modulator control circuit MSS.

On the output side of the rectifier circuits, in addition to the smoothing capacitor C2, a resistor R2 and a Zener diode DZ or a parallel voltage regulator are provided, so that regardless of whether the normal bridge rectifier circuit or the voltage doubling rectifier circuit is active, the same supply voltage U _V is present at the output is available. The voltage regulation via the Zener diode only takes effect when the voltage rises above the desired value. Then it is not disturbing if a power loss is generated in the Zener diode DZ. For modulation itself, however, no load resistor is switched on in the circuit arrangement of the data carrier according to the invention.

FIGS. 5 and 6 show oscillograms a data carrier according to the prior art and of a data carrier according to the invention. The current i _L11 or i _{L1 is} plotted in the coupling element, that is to say the coil L11 or L1, the supply voltage U _V at the output of the rectifier circuits and the data signal 12 . While, according to the prior art, the supply voltage U _V drops sharply during the connection of the load, the supply voltage in the circuit arrangement of the data carrier according to the invention is only insignificantly lower. The amplitude of the coil current differs in both cases by approximately 2.5 mA, so that there are no disadvantages for the reader when recognizing the modulated signal. While in Fig. 5 after switching off the load, the amplitude of the current i _L11 only increases slowly, the amplitude of the current i _L1 in FIG. 6, that is to say with the data carrier according to the invention, quickly increases to its maximum value. This is also a further advantage in the design of a data carrier according to the invention.

Claims (6)

1. Contactless data carrier with
a coupling element (L1),
a first and a second rectifier circuit, which have different input resistances and whose inputs are connected or connectable to the coupling element (L1), for obtaining a DC voltage (U _V ) from an AC voltage generated in the coupling element (L1),
a switch (S1), which is connected to a modulator control circuit (MSS), for switching between the two rectifier circuits, so that the DC voltage U _{V is} generated by one and / or the other rectifier circuit and
a voltage control circuit (DZ) which is connected or can be connected to outputs in the rectifier circuits. 2. Contactless data carrier according to claim 1, characterized in that the first and the second rectifier circuit ge together have used components (D1, D2). 3. Contactless data carrier according to claim 1, characterized in that one of the rectifier circuits a voltage multiplier rectifier circuit. 4. Contactless data carrier according to claim 1, characterized in that the voltage regulator (DZ) is a parallel regulator. 5. Contactless data carrier according to claim 3, characterized in that
the voltage multiplying circuit is a Villard circuit in which a first connection of a coil (L1) forming the coupling element is connected to a first connection of a first capacitor (C3),
a second connection of the coil (L1) is connected to a second connection of the first capacitor (C3) via a first diode (D1),
the second connection of the first capacitor (C3) is connected to a first DC voltage output via a second diode (D2),
wherein between the second terminal of the coil (L1) and the first diode (D1) a third diode (D3) is connected, which can be bridged by a switch controllable by the modulator control circuit (MSS), and
wherein a fourth diode (D4) is connected between the second connection of the coil and the first DC voltage output and
wherein the connection between the third and the first diode forms a second DC voltage output. 6. Contactless data carrier with
a coupling element (L1),
a rectifier circuit for obtaining a direct voltage (UV) from an alternating voltage generated in the coupling element (L1),
a switch connected to a modulator control circuit (MSS), by means of which an energy store can be connected to the coupling element (L1) in a charging phase, the energy store representing a load, and
a voltage control circuit (DZ), which is connected to the rectifier circuit and the energy store, the energy stored in the energy store being able to be discharged in a discharge phase into a sink connected to the output of the rectifier circuit.