DE4220597C1 - Digital signal coding method e.g. for computer network - generating data pulses with three or more pulse widths dependent on pulse widths and polarities of preceding pulse(s) - Google Patents

Abstract

Th e coding method is for digital signals which represent the logic levels "1" or "0" and which take on the signal value within a bit period which is determined by the data rate. The maximum pulse width of the data pulses is equal to half a bit period. An insignificant compensation pulse is inserted between two pulses of the same polarity . The data pulses are produced with at least three different pulse widths (A,B,C) and each pulse width depends on the pulse widths and polarity of the preceding pulse, pref. the two preceding pulses. The pulse widths of sequential pulses are always different. ADVANTAGE - Allows plausibility check by detecting inconsistency of one pulse w.r.t. previous pulses.

Description

The invention relates to a coding method for digital Signals that logically represent "1" or "0" and the Signal value within a determined by the data flow rate Assume bit period in which the data pulses have a pulse width of a maximum of half a bit period and between two pulses of the same polarity a non-significant one Compensation pulse of opposite polarity is inserted.

Such a coding method is, for example, by US 33 31 079 or EP 00 74 587 B1 known. The addition of the unsignificant compensation impulses leads to the Generic coding method that always a pulse one polarity is followed by a pulse of the other polarity. If this is already given by the data impulses themselves, arises nothing special. However, data pulses follow the same Polarity to each other, leads to the insertion of the compensation pulse opposite polarity to the desired one consequent alternation of impulses different Polarity. In this way it can be avoided that disruptive resulting DC voltages by a plurality built up by successive pulses of the same polarity will. The disruptive DC voltages can  Record the pulses on a magnetic material too lead to its saturation and therefore impair the recording. In computer networks, the emerging ones DC level can cause ground loop problems.

With the known coding methods self-clocking Signals are realized so that the transmission of separate clock signals is unnecessary.

Testing the functionality of devices using such coding methods work is cumbersome about a comparison of the original signals with those given coded signals possible. Such a comparison allows just a random check.

The invention has for its object a coding method of the type mentioned at the beginning and the function check a coding device operating according to the coding method to improve.

This object is achieved using a Coding method of the type mentioned at the outset solved by that the data pulses with at least three different Pulse widths are generated and that the respective pulse width depending on the pulse widths and polarities of previous impulses.

While the known coding method with the same Pulse width for the data pulses and the compensation pulses work, according to the invention is a variation of this Pulse widths are provided so that certain pulse widths only may occur due to certain conditions caused by previous pulses and their pulse width are set. The coding method according to the invention thus at least allows a plausibility check that checks the consistency of a occurring pulse width with previous pulse polarities  and widths. If there is a lack of consistency an error message is output.

In principle it is possible to vary the pulse width in this way train that a certain sequence of previous ones Pulse polarities and widths uniquely to one determined pulse width, so that conversely the pulse width variations for decoding the coded signals can be used by a recipient of the encoded signal a restoration of the original Signals, be it as RZ- (return to zero) or NRZ (no return to zero) signal, eliminating the compensation pulses by a clear prediction of the next signal value he follows.

According to the invention only on the received coded signal possible plausibility check enables a To create a test facility that consists exclusively of the encoded signals determines whether the coding is error-free is working.

With a manageable effort both on the coding and the coding method according to the invention can be found on the test side realize when the pulse width of a pulse depending on the pulse widths and polarities of the two previous impulses.

It is useful if the pulse widths are consecutive Impulses are always different.

The process according to the invention can be carried out with an appropriate one Compromise between effort and testability preferred with three different pulse widths for the Realize data impulses.

It is useful if different Polarities of successive data pulses on the first  Pulse width and on the third pulse width always the second Pulse width and on the second pulse width the third Pulse width if the second pulse width is the first pulse width before, and the first pulse width follows when the second pulse width was preceded by the third pulse width, and if consecutive data pulses have the same polarities the first and third pulse width alternately occur, the first time the same Polarities according to different polarities as Transition pulse designated data pulse occurs and where in the event that the transition pulse is the second pulse width has the resulting pulse width after the transition pulse equal to that of the data pulse before the transition pulse is.

This procedure results in alternating polarities at three Pulse widths (A), (B), (C) in an order A-B-C-B-A-B- C-. . ., with the same polarities for the sequence A-C-A-C-A-C-. . . The transition to the same polarities arises for the second pulse width (B), the rule applies that the following pulse width is the same as that before the transition pulse previous pulse width is. This coding method leaves easy to realize and leads to an almost safe Error detection rate in the plausibility check of the coded signal.

For the plausibility check, a variation of the Pulse width of the compensation pulses is not required. It is therefore possible with a constant pulse width Compensation pulses to work. When using three Pulse widths are preferably equidistant from one another, so that the sum of the first and third pulse widths is equal is twice the second pulse width. When using is a constant pulse width for the compensation pulses the pulse width of the compensation pulses is preferably the same the second pulse width.  

Since a coding device according to the invention will be able to must generate different pulse widths, it can without great additional effort can be exploited at the same time adapt the pulse widths used to the data flow rate, so that, for example, an adjustment of the pulse width under the aspect of an optimal signal-to-noise ratio can take place, whereby the transmission of the coded pulses can be done with optimal transmission security.

The invention is based on one in the drawing illustrated embodiment explained in more detail. It shows

Fig. 1 - schemes for pulse widths with regularly alternating polarities or with regularly the same polarities

Figs. 2a and b - examples of pulse waveforms having different transitions between the regular curves of Figure 1.

Fig. 3 - is a flow chart for explaining the generation of the coded pulses according to the Figures 1 and 2.

FIG. 4 - is a block diagram of a coding circuit for performing the encoding according to FIGS. 1 to 3.

Fig. 1 shows three basic pulse waveforms. The top line shows alternating signals between "1" and "0" that lead to alternating polarities. A pulse duration is entered in the corresponding pulses, three pulse durations being provided, namely a first pulse duration A of 8 ns, a second pulse duration B of 10 ns and a third pulse duration C of 12 ns.

Fig. 1 illustrates that with constantly alternating polarities, the order of the pulse duration ABCBABCB-A-. . . is. In this case, since the data pulses have alternating polarities, no compensation pulses are required.

The states in which pulses of the same polarity follow one another are shown in the second and third lines of FIG. 1, either only positive polarities - corresponding to logic "1" - or negative polarities - corresponding to logic "0" -.

In this case the data pulses are alternating Pulse widths A-C-A-C-A-C-. . .

Since the data pulses all have the same polarity, there is a compensation pulse K between each of them with a constant pulse width of 10 ns.

In FIGS. 2a and 2b, one row examples of pulse sequences are shown. Bit periods in which a transition to a sequence of the same priorities takes place for the first time are particularly marked. The data pulses located in this bit period are also referred to below as "transition pulses" Ü.

If the transition occurs with a transition pulse with a pulse width A or C (8 ns or 12 ns), there is no special feature, since the transition pulse fits into the diagram from FIG. 1 for pulses of the same polarities (alternating ACA, etc.).

However, if a transition occurs at a transition pulse with pulse width B, the rule is applied that the subsequent pulse has the same pulse width as the pulse preceding the transition pulse Ü, as is the case, for example, on the second transition in all lines - with the exception of the lower line - can be seen in Fig. 2a.

FIG. 3 shows a flow chart in which the decision steps for the formation of the respective pulse widths and pulse types are shown.

In step 10 , the pulse N (n) is transmitted for a bit period corresponding to a data value. In a manner known per se, the data signal of this bit period is compared in step 11 with the data signal of the following bit period. Naturally, this requires that - in accordance with the known coding methods - there is a delay of at least one bit period in order to be able to carry out the comparison. If the polarity of the pulse is equal to the polarity of the subsequent pulse, a compensation pulse is inserted in step 12 , which has the pulse width B and has a reverse polarity as the pulse N (n).

In step 13 it is checked whether the pulse width of the pulse corresponds to the pulse width A. If this is the case, it is determined in step 14 that the pulse width of the next pulse is C and that the next pulse is transmitted with the same polarity as the previous pulse.

If it is found in step 13 that the pulse width is not A, it is checked in step 15 whether the pulse width is C. If this is the case, the pulse duration for the next pulse with the pulse duration A is determined in step 16 and the polarity of the next pulse is equal to the polarity of the previous pulse.

If the check in step 15 shows that the pulse width is not C, only the pulse width B remains. In step 17 it is therefore determined that the next pulse has the pulse width of the previous pulse and that its polarity corresponds to the polarity of the current pulse.

If it turns out during the check in step 11 that the values of the successive data are not the same, it is checked in step 18 whether the pulse has the pulse duration B. If this is not the case, according to the rule ABCBABCB-. . . just follow pulse width B. It is therefore determined in step 19 that the pulse width of the next pulse is B and that the next pulse has a polarity which is reversed from the current pulse.

If, on the other hand, the pulse width B is determined in step 18 , the current pulse is replaced by the previous pulse in step 20 and passed to decision stage 13 . If the previous pulse had the pulse width A, the pulse width C is determined for the next pulse in stage 14 , the pulse (n + 1) having the same polarity as the pulse (n-1).

If the (n-1) pulse did not have pulse width A, it could only have had pulse width C, since pulse (n) had pulse width B and never two consecutive data pulses have the same pulse width. Accordingly, the pulse width C is determined to be correct in the decision stage 15 , whereupon the pulse width A is set for the pulse (n + 1) in the stage 16 and the polarity is selected to be equal to the polarity of the pulse (n-1).

In this way, all conceivable constellations are taken into account, and the pulse width and polarity of the next pulse has been determined in accordance with the diagram of FIGS. 1 and 2. In stage 21 , the next pulse is then set as the output pulse for the new cycle.

FIG. 4 shows a circuit for implementing the coding according to FIGS. 1 and 2 and for carrying out the decision processes according to FIG. 3.

The data to be coded arrive at a switching stage 30 which, using flip-flops, provides three successive data values at three outputs. These data values are referred to as Data -1, Data, Data +1. In this terminology, Data -1 is the previous data signal, Data the current data signal and Data +1 the upcoming data signal. The control signals for three possible pulse widths are generated in a programmable logic array 31 as a function of the values of the three data Data -1, Data and Data +1 present. The three outputs of the programmable logic array 31 arrive at three inputs of a multiplexer 32 . This combines the inputs with signals present at three other inputs, which have been delayed by a programmable delay line 33 and a delay line 34 with three taps. A delay of 3, 4, 5 or 6 ns can be set with the programmable delay line. The delay line 34 has three taps by which the input signal has been delayed by 2 or 2.5 ns more. If a delay time of 6 ns has been set with the programmable delay line, a total delay time of 8, 10 and 12 ns can be tapped at the taps T1, T2, T3 of the delay line 34 . The multiplexer 32 is therefore used to set the pulse widths of, for example, 8, 10 and 12 ns via the available delayed signals.

The output signal of the multiplexer 32 arrives at two inputs of two multiplexers 35 and 36 , which each generate the data signals and compensation signals for the positive ( 35 ) and the negative ( 36 ) polarity.

With the aid of the programmable delay line 33 , the pulse widths A, B, C and K can be adapted to the bit rate if different bit rates should be used. A fixed delay line 37 is used to generate a trigger pulse which has a defined position in time after the beginning of the bit period.

The selection of the applicable pulse width is thus carried out in the programmable logic array 31 , while the polarity of the next pulse is selected with the multiplexers 35, 36 .

Claims (9)

1. Coding method for digital signals which logically represent "1" or "0" and assume the signal value within a bit period determined by the data flow rate, in which the data pulses have a pulse width of at most half the bit period and a non-significant compensation pulse between two pulses of the same polarity is inserted, characterized in that the data pulses are generated with at least three different pulse widths (A, B, C) and that the respective pulse width (A, B, C) depends on the pulse widths (A, B, C) and polarities of the preceding ones Is impulses. 2. Coding method according to claim 1, characterized in that that the pulse width (A, B, C) of a pulse depends on the pulse widths (A, B, C) and polarities of the two previous impulses. 3. Coding method according to claim 1 or 2, characterized characterized in that the pulse widths (A, B, C) successive impulses are always different. 4. Coding method according to one of claims 1 to 3, characterized by using three different ones Pulse widths (A, B, C).   5. Coding method according to claim 4, characterized in that with different polarities consecutive Data pulses on the first pulse width (A) and to the third pulse width (C) always the second pulse width (B) and on the second pulse width (B) the third Pulse width (C) if the second pulse width (B) is the first pulse width (A) and the first Pulse width (A) follows when the second pulse width (B) the third pulse width (C) preceded and that with the same polarities successively Data pulses the first and third pulse width (A, C) alternate, with the first appearance the same polarities after different Polarities a referred to as a transition pulse (Ü) Data pulse occurs and in the event that the Transition pulse (Ü) has the second pulse width (B), the pulse width arising after the transition pulse (Ü) equal to that of the data pulse before Transition impulse (Ü) is. 6. Coding method according to claim 4 or 5, characterized in that the sum of the first and third pulse widths (A + B) equal to twice the second pulse width (2B) is selected. 7. Coding method according to one of claims 1 to 6, characterized characterized in that the compensation pulses have constant pulse width (K). 8. Coding method according to claim 6 and 7, characterized in that the pulse width (K) of the compensation pulses is equal to the second pulse width (B). 9. Coding method according to one of claims 1 to 8, characterized characterized in that the pulse widths (A, B, C, K) to the Data flow rate can be adjusted.