DE19744782A1 - Method of data communications between a read-write device and a transponder - Google Patents

Abstract

The method involves varying the field strength of an alternating electromagnetic or magnetic field and evaluating the times between successive field strength changes. The input resonant circuit of the transponder is damped in the same sense as the alternating field strength and/or a threshold of the transponder receiver is shifted in the same sense as the filed strength.

Description

The invention relates to a method and an apparatus for Data transfer between a read / write device and a Transponder according to the preambles of claims 1 and 14.

Systems of read / write devices and transponders are used for contactless identification of objects, people and Animals. The transponder is a data storage device whose information read and wireless with the read / write device can be changed.

The information is transmitted magnetically or electrically magnetic. To achieve high input sensitivity the receiver and thus a long range and interference to suppress conditions from other frequency ranges are both sides used resonant circuits, whose coils the Kopp manufacture lung. The data transfer from the reader to The transponder is changed by changing the field strength and evaluating the Times between successive changes in field strength performed.  

Systems that are suitable for data transmission too electrically and magnetically conductive materials between Penetrating transmitter and receiver work with one low carrier frequency. If still a usable one Transmission speed is to be reached Data rate relatively high in relation to the carrier frequency. From depending on the carrier frequency and the quality of the input resonant circuit are its settling and decay times. she play a significant role when their times in the are of the same order of magnitude as the period of the Da signals. This limits the swing-in and swing-out times of the Input resonant circuit the maximum data rate.

The invention has for its object a method and a device for data transmission between a write To improve the reader and a transponder that even at a low carrier frequency, a high maxima le data rate can be achieved.

This task is carried out in a method according to the generic term of claim 1 and a device according to the preamble of claim 14 by the specified in the respective indicator characteristics resolved. Further training and advantageous Aus  designs of the invention result from the dependent claims chen.

The solution according to the invention is based on the following consideration. The length of the settling and decay times is determined by the quality of the resonant circuit of the receiver, which is indeed in Nor should be particularly high so that interference from others Frequency ranges are suppressed and a high input sensitivity is achieved. However, just that distort The pulse decays so that it follows at short intervals pulses can no longer be distinguished from one another and decoding becomes incorrect. However occurs this effect only at high field strengths, while at low field strengths the distances between successive gender pulses can be detected. The field strength level z. B. if the distance between the Read / write device and the transponder changes. It was previously assumed that the switching threshold of a Kompara tors in the receiver, which is between the existence and the Difference of a carrier differs and thereby allows the detection of pulses and pauses is constant.

However, if the switching threshold of the comparator and the ma ximal voltage at the input resonant circuit in a suitable manner related, it succeeds in pulses in which the  Porters are present, and breaks during which they are absent is to be distinguished independently of the field strength. This is thereby possible that with constant switching threshold of the Kompa rators the input resonant circuit is fought so that a largely the same ratio between maximum amplitude and switching threshold is achieved or that the switching threshold is moved with and in this way also a weitge same ratio between maximum amplitude and shifted switching threshold is maintained. Also one A combination of both measures is possible.

In all cases the resonance circuit will then decay voltage detected earlier after switching off the carrier and there the breaks after pulses can be better identified ren and thus also in short intervals in succession Differentiate pulses. At low field strength, however, remains maintain the high input sensitivity and selectivity.

According to a further development, the time constant with which the Damping measure depending on the field strength of the alternating field is changed and / or the switching threshold of the receiver of the The transponder is moved larger than the period successive field strength changes for the purpose of Da transmission selected.  

If the resonant circuit is closed when a field strength increase begins next undamped and only starts damping, when the resonant circuit voltage exceeds a switching threshold tet, you can do without a time constant. Then it's one very fast adaptation to changing transmission ratios nisse possible. With constant damping of the resonant circuit and / or shift of the switching threshold but is by On keeping a time constant achieved that damping not already the rapid field strength changes in which the transmitted data are encoded, and consequently the Detection of these field strength changes would be impaired.

When the resonant circuit is damped, the damping dimension follows in Ab dependence of the field strength of the alternating field of a characteristic curve, which the maximum resonant circuit amplitude to a value borders, which is of the same order of magnitude, but above that Input sensitivity and / or a switching threshold of Recipient.

This ensures that at the end of a pulse at high Field strength and the resonant circuit amplitude much faster ter the switching threshold of the receiver drops as if the Would oscillate freely. The limitation leads that even the same decay times are achieved,  as with very low field strengths even without the inventions appropriate measure would occur.

A control signal for controlling the damping is preferably used and / or the switching threshold from the resonant circuit voltage headed.

Apart from a control deviation when controlling the Attenuation results in a very tight coupling between the Field strength as a controlling variable on the one hand and the attenuation or the switching threshold on the other. This enables the Decay times are almost independent of the current field keep strength constant.

The maximum resonant circuit amplitude can be set to a fixed value be limited.

It is then only a simple circuit required, the z. B. with a passive voltage limiter instead of a Re gel circuit gets along. However, as a voltage limiter not the protective circuit for protection that is usual with transponders of electronic components suitable for overvoltage, son the limitation must be to very low values in the range of Receiver sensitivity, which is a few millivolts, be will measure. The disadvantage is that with this solution none  Component tolerances, the z. B. determine the switching threshold, can be taken into account.

But it can also the maximum resonant circuit amplitude on egg be limited to a predetermined constant or variable switching threshold is adjusted so that a constant distance between maximum resonant circuit amplitude and switching threshold results.

With this solution, which is more complex in terms of circuitry and can be realized with a control circuit component tolerances or other influences on the receiver sensitivity and / or the switching threshold by a constant distance between the maximum The resonant circuit amplitude and switching threshold becomes a constant Decay time regardless of the above influences ensures.

A further training provides that the maximum oscillating cycle samplitude and / or the switching threshold in the receiver to one value determined by the sender and transmitted to the receiver is limited.  

In this way it is possible without mechanical intervention the transponder the values by programming the transpon adapt to changed operating conditions.

It can also be provided that with a field strength increase hung and identification of a useful signal carrier of the on gating resonant circuit of the transponder only after a given a delay time is dampened.

At the beginning of a pulse, the maximum quality is then reached exploited the resonant circuit to useful signals against interference to be able to identify Only after detection of Useful signals use damping to reduce the swing-out time to limit the pulse.

The specified delay time can be determined by an analog Timing element and / or digital by counting carrier vibrations read / write device or pulse an internal time basis.

The damping of the input resonant circuit is preferred of the transponder over the end of through a subsequent one Field strength reduction defined pulse duration upright received but before an expected entry of another Field strengthening ended.  

If the damping of the input resonant circuit of the Transpon which is maintained beyond the pulse duration the decay time is further reduced. The necessary break until the next pulse, this can also reduce further be tied.

The duration of the damping can be controlled by an analog timer and / or digitally by counting carrier vibrations of the Read / write device or pulse an internal time base be averaged.

According to a further embodiment of the invention, that upon detection of an increase in field strength, the input resonant circuit of the transponder regardless of the current value the field strength is damped and the damping at least until the expected occurrence of a subsequent field strength reduction is maintained but before an expected A renewed increase in field strength is terminated.

This solution requires that the length of the field strength no changes defined pulses in which a carrier is present and breaks in which there is no porter are known is. It is then sufficient that the appearance is different to recognize pulses. The actual end of a pulse  is then of no importance. The specified measurement of time, in which the resonant circuit is damped ensures that a further pulse can be clearly recognized again. With the This measure can reduce the effective decay time of a pulse be reduced to almost zero. Another advantage of this Measure is based on a variation in damping Dependency of the field strength to be able to do without.

The degree of damping is expediently at least so great that the resonant circuit chip even at the maximum possible field strength voltage drops below a switching threshold of the receiver.

The damping is dimensioned to the specified value light it, all field strengths possible in practical operation to be able to master the rich equally.

The invention is based on the drawing he he purifies. In this show:

Fig. 1 is a timing diagram of transmitted and receive pulses with different ner Datenra te,

Fig. 2 is a simplified block diagram of a read-write device and a transponder with a controlled attenuator parallel to the input resonant circuit and

Fig. 3 is a timing diagram of a pulse on an input resonant circuit with and without damping.

Fig. 1 shows a timing diagram of transmitted and received Pul se with different data rate. In Fig. 1a pulses are shown as they are transmitted from the transmitter. The pulses are caused by the presence of a carrier while the carrier is switched off in the pauses in between. The length of the pulses and / or the length of the pauses between the pulses encodes the data to be transmitted. While the distances between the individual pulses on the left in the illustration are long and the data rate is therefore low, the data rate on the right changes to higher values, ie the distances between the pulses are shown to be shorter.

In Fig. 1b below the corresponding resonant voltage at the input resonant circuit of the transponder is shown as it follows the transmitted pulses. The quality of the resonant circuit results in settling and decay times. At the beginning of a pulse, the resonant circuit voltage rises to a maximum value and drops after the pulse. The rise and the drop in voltage follow an e-function. Furthermore, a switching threshold of the receiver is shown in Fig. 1b, during the passage of which the beginning or the end of a pulse is registered.

As the illustration shows, the resonant circuit voltage drops low data rate in the pauses between the pulses ter the switching threshold of the receiver, so that the individual Pulse can be distinguished from each other. In contrast, decreases at a higher data rate, the resonant circuit voltage is no longer un ter the switching threshold, so that then the one behind the other of the following pulses identified as a single pulse the and the breaks no longer as a separation between the pulse can be evaluated. As the presentation continues the swing-out times are particularly critical since here with values close to the switching threshold of the receiver the slope of the falling flank is particularly low, while at the same value the slope of the rising Flank is still relatively large.

In Fig. 2, a simplified block diagram of a read-write device 10 and a transponder 12 with a controlled attenuator 14 parallel to the input resonant circuit 16 is shown. The read / write device 10 transmits data consisting of a sequence of pulses with the carrier switched on and pauses with the carrier switched off via its transmission resonant circuit 18th The magnetic or electromagnetic alternating field is picked up by the input resonant circuit 16 of the transponder 12 and, depending on the quality of the resonant circuit 16, an oscillating circuit voltage is set which follows the field strength changes of the transmitting resonant circuit 18 with a delay. A controllable attenuator 14 is arranged parallel to the input resonant circuit 16 and is controlled by an amplifier 20 , which receives its input voltage from the input resonant circuit 16 . The amplifier 20 activates the attenuator 14 when the voltage at the output of the amplifier 20 has risen to such an extent that the defined switching threshold of a subsequent Schmitt trigger 22 has been exceeded. The signal at the output of the Schmitt trigger 22 is finally fed to a decoder (not shown here) for evaluation.

The variable attenuator 14 is controlled so that its damping increases with increasing resonant circuit voltage, so that the resonant circuit voltage is kept largely constant taking into account a re gel deviation. This corresponds to a limitation of the resonant circuit voltage.

Fig. 3 shows the effects of this action on the basis of the time chart of a pulse at the input resonant circuit with and without attenuation.

The pulse width is assumed to be the same in both cases. The voltage curve a shows a behavior in which the Resonant circuit has a high quality, so only low ge is dampened. The tension gradually reaches a maximum worth, whose absolute size also depends on the field strength is. If the carrier is switched off at a time T0, the resonant circuit voltage gradually drops and falls below finally, at a time T2 the switching threshold of Recipient.

In contrast, curve b shows a behavior that is characterized by ge controlled damping of the input resonant circuit results. Here sets the dampers after the resonant circuit voltage rises setting that is just controlled so that the maximum Oscillating circuit voltage only slightly above the switching threshold of the recipient. The carrier will be in the same If time T0 is switched off, the resonant circuit voltage drops approximately with the same slope as curve a. However, since the maximum value of curve b is much lower than at curve a, the switching threshold is already in the point of time Falling below T1, which is much earlier than time  point T2. In this way it is achieved that the effective Decay time is shortened and therefore also with high field Strengthen successive pulses sufficiently from each other can be distinguished. This means a higher data rate possible.

Claims (15)

1. A method for data transmission between a read / write device and a transponder by changing the field strength of an electromagnetic or magnetic alternating field and evaluating the times between successive field strength changes, characterized in that the input resonant circuit of the transponder is damped in the same direction as the field strength of the alternating field and / or one Switching threshold of the transponder receiver is shifted in the same direction as the field strength of the alternating field. 2. The method according to claim 1, characterized in that the time constant with which the damping measure is dependent the field strength of the alternating field is changed and / or the Switching threshold of the transponder receiver shifted becomes larger than the period of successive fields changes in strength for the purpose of data transmission. 3. The method according to claim 1 or 2, characterized net that the damping measure depending on the field strength of the Alternating field follows a characteristic curve that is the maximum  Resonant circuit amplitude limited to a value in the same order of magnitude, but above the input sensitivity and / or a switching threshold of the receiver. 4. The method according to any one of claims 1 to 3, characterized ge indicates that a control signal for controlling the damping and / or the switching threshold from the resonant circuit voltage is directed. 5. The method according to claim 3, characterized in that the maximum resonant circuit amplitude to a fixed value is bordered. 6. The method according to claim 3 or 4, characterized in net that the maximum resonant circuit amplitude to a value is limited to a given constant or varia ble switching threshold is adjusted so that there is a constant Distance between maximum resonant circuit amplitude and switching threshold results. 7. The method according to any one of claims 3 to 6, characterized ge indicates that the maximum resonant circuit amplitude and / or determine the switching threshold in the receiver to one from the transmitter and the value transmitted to the recipient is limited.   8. The method according to any one of claims 1 to 7, characterized ge indicates that with a field strength increase and Identifi cation of a useful signal carrier the input resonant circuit of the Transponders only after a specified delay time is dampened. 9. The method according to claim 8, characterized in that the specified delay time by an analog time link and / or digital by counting carrier vibrations the read / write device or pulse an internal time base is determined. 10. The method according to claim 8 or 9, characterized in net that the damping of the input resonant circuit of the Trans ponders beyond the end of a subsequent field strength maintenance of the defined pulse duration but before the expected occurrence of a new field strength no increase is ended. 11. The method according to claim 10, characterized in that the damping duration by an analog timer and / or digitally by counting carrier vibrations of the writing Reader or pulses an internal time base determined becomes.   12. The method according to claim 1, characterized in that upon detection of an increase in field strength, the input vibration circle of the transponder regardless of the current value of the Field strength is damped and the damping at least up to on the expected occurrence of a subsequent field strength reduction change is maintained, but before an expected change occurs a further increase in field strength is ended. 13. The method according to claim 12, characterized in that the degree of damping is at least so large that also at maximum possible field strength below the resonant circuit voltage a switching threshold of the receiver drops. 14. Device for data transmission between a writing Reader and a transponder by changing the field strength nes electromagnetic or magnetic alternating field and Evaluation of the times between successive field strengths Ke changes with a resonant circuit at the entrance of the transpon ders, characterized in that parallel or serial to Resonant circuit of the transponder a controllable attenuator is arranged, the degree of damping in the same direction to the field strength of the alternating field is controlled and / or that the loading tensile value of a voltage comparator in the receiver in the same direction is controlled to the field strength of the alternating field.   15. The apparatus according to claim 14, characterized in that a control input of the attenuator and / or the span voltage comparator is connected to a control circuit, de Ren input signal directly from the resonant circuit voltage is leading.