DE3028582A1 - Data transfer device - has logic level shift compensation involving maintenance of logic one state according to reference signal - Google Patents

Abstract

The data transfer device frequency selectively reflects an interrogation signal from an interrogating device according to multiple location binary data associated with a responder. It enables compensation of shifts in the signal condition logical 'l' of the useful signal condition series. Each logical 'l' condition of the useful signal (2) as maintained by a signal shaping circuit until a change from 'l' to '0'of the reference signal (1) and is immediately preceded by a change from '0' to 'l'. This is followed by a useful signal transition from 'l' to 'o'. The logic level at the output of the shaping circuit is monitored at evaluation intervals defined by the change from 'O' to 'l' of the reference signal (1). The shaping circuit may consist of a NOT element with three flip-flops.

Description

Information transmission device in which an interrogation

signal is reflected frequency-selective The invention relates to an information transmission device, in which one of an interrogation device emittable periodically tunable interrogation signal from a transponder accordingly a multi-digit binary information assigned to this is reflected in a frequency-selective manner is, whereby a binary useful signal status sequence with a predetermined in the interrogator Time grid is formed, each for the serial detection of the information to a binary reference signal state sequence at specified evaluation times whose period duration is the specified time for a raster step is equivalent to.

To transfer information from a transponder to an interrogator, without an energy source being provided on the part of the transponder for this purpose Facilities of the type mentioned have been developed. Such a facility, which, in particular due to temperature differences between the response and the interrogation device resulting time shift of the useful compared to the Compensates reference signal state sequence is already known from DE-PS 1 591 595.

However, this facility does not allow for displacements of the signal states logically equalize U1 of the useful signal state sequence against each other.

The object of the invention is to provide a device of the type mentioned at the beginning Generate to be trained so that shifts of the signal states logic "1" of the useful signal state sequence can be compensated against each other.

According to the invention, this object is achieved in that a shaper circuit to maintain each signal state logical "1" of the useful signal state sequence in each case up to a signal state change from logical 1 to logical "0" of the reference signal state sequence is provided, which a signal state change of the reference signal state sequence from logic "0 'to logic" 1 "immediately precedes the signal state change The useful signal status sequence immediately follows from logical "0 'to logical" 1, and that a circuit for determining a first or a second logical identifier if there is or is not a signal state logical "1" at the output the shaper circuit is provided at evaluation times, each by the signal state change from logic "0" to logic 1 "n of the reference signal state sequence are determined. This enables shifts in the signal states to be logically "1" equalize within a full grid step.

An advantageous embodiment of the invention is characterized in that that for the shaping circuit one NOT element and three by signal state change from logic "0" to logic tt1 n at one C input each via one D input controllable, each one dominating over this R and one S input and flip-flops each having a Q output are provided, that the reference signal state sequence is directly connected to the C input of the first and the second and the C input of the third flip-flop element via the NOT element fed is that the Q output of the first with the R input of the second and its Q output are connected to the D input of the third flip-flop that the D input of the the second flip-flop is constantly subjected to a signal state of logic "0", that the useful signal status sequence to the D input of the first to the S input of the second and third flip-flop is performed and that its Q output is the output the forming circuit forms. This is a technically extremely simple training the former circuit guaranteed.

Such an information transmission device can be set in a basic position have a transmitter device that briefly emits a signal state logical "1" to the S input of the first and to the R input of the third Flip-flop creates.

An embodiment of the invention is shown in the drawing and is explained in more detail below.

The figures show: FIG. 1 a block diagram of the invention and FIG 2 several diagrams for the block diagram.

The illustration according to Figure 1 shows an interrogation device AB, which a periodic Frequency-adjustable microwave interrogation signal to a transponder AN transmits which, according to information to be transmitted, this interrogation signal as a response signal, frequency-selective reflected to the interrogator AB (through open Arrows indicated) by attenuating individual frequencies of a frequency grid. In the query device AB there is a circuit for basic temperature compensation intended.

In the illustration according to FIG. 2, five signal state sequences are shown as Signal state-time diagrams 1 to 5 shown with the same time scale on for the further description of the device according to Figure 1 in the following reference is taken. The same time periods during which one grid step of the Frequency raster is indicated by the numbers I to VII.

A binary symmetrical reference signal state sequence is generated in the interrogator AB generated whose period corresponds to the specified time for a raster step.

This reference signal state sequence (diagram i) is transmitted via a line L1 forwarded.

Furthermore, in the interrogator AB is reflected from the reflected by the transponder AN Query signal a useful signal status sequence (diagram 2) obtained in which the occurrence or no signal status changes from logical "0" to logical "1" the information from the transponder AN in the successive grid steps indicates. In the selected embodiment, occur at any time within of the time periods I, III, IV and V signal state change from logic "0" "to logic "1", while in the time segments II, VI and VII no such signal state changes are present. The useful signal status sequence is sent from the interrogator AB via a line L2 output.

The lines L1 and L2 lead to a shaping circuit F, which is shown in dashed lines is shown and an evaluation device also indicated by dashed lines A is connected downstream.

The shaper circuit F consists of a NOT element N and three flip-flops K1 to K3. These are due to a signal state change from logical "0" to logic 1 at one C input each via a D input with dominant setting or. Reset inputs R and S Furthermore, one is not in each case The inverting Q output of the flip-flops K1 to K3 is connected.

Via a button T serving as a transmitter device, which is used to initiate a basic position for the former circuit F briefly the signal state logical g is applied to the S input of the flip-flop element K1 and the R input of the flip-flop element K3, the signal state logic 1 is impressed on the Q output of the trigger element K1, the The flip-flop element K2 is influenced via a line L3 in such a way that the Q output of the flip-flop Signal state logic 0 "is present.

Furthermore, the key T also activates the flip-flop K3 via its S input set so that the Q output of the flip-flop K3 has the signal state logic 1.

The reference signal state sequence is assigned to the C inputs of the flip-flops K1 and K2 fed directly. The flip-flop K3 is the reference signal state sequence over the NOT element N supplied inverted. With every signal state change from logical The Q output of the flip-flop takes "0" to logical 1 of the reference signal state sequence K1 shows the signal state present at its D input. That is, only then the signal state logic 1 is present at the Q output of the flip-flop K1 if a signal state logical 1 of the useful signal status sequence during the signal status change from logical "0" is present at logical 1 of the reference signal state sequence. Any signal state Logical 1 at the Q output of the flip-flop K1 is then state until the next signal Change of the reference signal state sequence from logical "0" to logical In sustained. This behavior of the signal states on line L3 is shown in diagram 3.

The useful signal state sequence is also used by the S inputs of the flip-flops K2 and K3 supplied. For the flip-flop K2, whose D input constantly shows the signal state logic 11011 leads, this usually means that via the S input of the flip-flop K2 immediately with the occurrence of the signal state logical "1" of the DJutz signal state sequence the signal state logic '1 "is impressed on the Q output, but due to the Signal state of logic "0" at the D input at the next signal state change from logic ItO to logic 1'111 of the reference signal state sequence reset to logic "Q" will.

But if the signal state is logical at the Q output of the flip-flop YJ "1" is present at the moment when the signal state is logical "1" of the useful signal state sequence changes to the signal state logical "0", the Q output of the flip-flop K2 Logical "O" state impressed. The output signal from the Q output of the flip-flop K2 reaches the D input of the flip-flop element K2 via a line L4. The signal state sequence at the output of the flip-flop K2 is shown in diagram 4 in FIG.

The Q output of the flip-flop K3 picks up at the same time as the Q output of the flip-flop K2 the signal state logic "1" as soon as the signal state is logic "1" occurs in the useful signal status sequence. With every signal status change from logical "1" to logical "o" of the reference signal state sequence becomes the logical state at the Q output of the flip-flop K2 the Q output of the flip-flop of K3 embossed. This Q output forms the output of the shaper circuit F. The signal state sequence at the Q output of the flip-flop K3 is shown in diagram 5 in FIG.

The Q output of the trigger element K3 is connected to the via a line L5 D input of a shift register S connected, the C input of which is connected to the reference signal state sequence is applied. This means that you know the logical signal states at the output of the former circuit F with each signal state change from logic "0" to logic "1" of the reference signal state sequence are stored in the shift register S. The outputs Q1 to Qn of the shift register S are directly connected to a processing device V. Instead of shown parallel transfer of the information of the shift register S to the Processing device V serial transmission would also be possible.

2 Figures 3 claims Blank page

Claims (3)

Claims 1. Information transmission device, in which a periodically tunable interrogation signal of a transponder corresponding to a multi-digit binary assigned to it Information is reflected in a frequency-selective manner, whereby a binary Useful signal status sequence is formed with a predetermined time frame, which for serial detection of the information at predetermined evaluation times is related to a binary reference signal state sequence, the period of which the corresponds to the specified time for a raster step, d u r c h k e n n -z e i c h n e t that a shaping circuit (F) for maintaining each signal state Logical 1 "n of the useful signal status sequence (2) in each case up to a signal status change provided from logic "1 n" to logic "0" of the reference signal state sequence (1) is, which a signal state change of the reference signal state sequence (1) from logical "0" to logic "1" immediately precedes the signal state change from logical "0" to logical "1" of the useful signal status sequence (2) immediately follows and that a circuit (s) for determining a first or second logical identifier when present or No signal state of logical "1" at the output of the former circuit (F) is provided in each case at evaluation times, which are each caused by the signal state change from logic "0" to logic 1 "of the reference signal state sequence (1) are determined. 2. Information transmission device according to claim 1, d a d u r c h e k e n n n z e i c h n e t that for the former circuit (F) a NOT element (N) and three by signal status change from logical Ist0 "to logical 1" n on, respectively one C input controllable via one D input each, one opposite each other this dominant R and an S input and each having a Q output Flip-flops (K1, K2, K3) are provided so that the reference signal state sequence (1) the C input of the first (Ki) and the second (K2) directly and the C input of the third flip-flop element (K3) via the NOT element (N) is fed that the Q output of the first (K1) with the R input of the second (K2) and its Q output with the D-input of the third flip-flop (K3) are connected that the D-input of the second Flip-flop element (K2) is constantly subjected to a signal state logically from, that the useful signal status sequence (2) to the D input of the first (K1), to the S input of the second (K2) and the third flip-flop (K3) is performed and that its Q output forms the output of the shaper circuit (F). 3. Information transmission device according to claim 2, d a d u r c h g e k e n n n z e i c h n e t that for setting the shaper circuit (F) in a Basic position to the S input of the first (K1) and to the R input of the third Flip-flop (K3) briefly a signal state logical by a transmitter device (T) 1 is switchable.