DE2114149A1 - Circuit arrangement for generating a correction signal for steepening the edge of pulses - Google Patents

Description

Circuit arrangement for generating a correction signal for the Edge steepening of pulses.

The invention relates to a circuit arrangement for generating a Correction signal for the steepening of the edge of pulses by adding differentiated ones Signal components of the input signal, consisting of the series connection of a first Differentiating stage for forming one of the first differential quotients of the input signal corresponding signal, an amplitude discriminator to suppress signal overshoot a second differentiation stage to form a second differential quotient of the input signal and an adding stage for adding the Correction signal formed in this way for the input signal.

In such known circuit arrangements, there are overshoots suppressed in the correction signal that the between the first and second Differential stage switched amplitude discriminator only the positive and negative Passes peaks of the signal corresponding to the first differential quotient. In the simplest case, the amplitude discriminator can consist of two antiparallel switched diodes exist. This circuit arrangement has the disadvantage that the Amplitude discriminator must be set so that even with the largest occurring The signal overshoots jump in the first differential quotient corresponding signal can be suppressed. But that means that with a small impulse jump the signal corresponding to the first differential quotient is completely suppressed Another factor is the amplitude dependence of this circuit. When the threshold voltage is reached, the amplitude of the first differential quotient increases the signal corresponding to the input signal behind the amplitude discriminator is stronger to than the amplitude of the pulse jump. This is the case with large pulse jumps Correction signal so large that it is disturbing in appearance occurs.

The object of the invention is to provide a circuit arrangement for generating a correction signal for the edge steepening of pulses by adding indicate differentiated signal components of the input signal, for which the amplitude of the correction signal is proportional to the amplitude of the pulse jump, whereby simultaneously Overshoots are suppressed in the correction signal.

According to the invention, the amplitude discriminator exists in the circuit arrangement of the type mentioned at the beginning of two parallel branches, each with a first cutting stage, a storage element, a voltage divider and a second cut-off stage, furthermore is the output of one switching stage between the storage element and the voltage divider connected, which with one of the first differential quotient of the input signal corresponding signal, and finally the two are parallel Branches each connected to an input of an adder stage.

The circuit arrangement according to the invention to the invention has the The advantage that the threshold values of the amplitude discriminator vary depending on the size of the correction signal set automatically so that only the Signal overshoots are cut off.

The Ampiftudendiskriminator contains a further flank steepening expediently two further switching stages, which have a phase reversal stage a signal corresponding to the first differential quotient of the input signal and their respective output with the corresponding output of the first switching stage connected is. Another possibility for flank steepening is that between the second differentiating stage and the adding stage one further cut-off stage and a third differentiation stage to form a dem third difforontial quotient of the input signal corresponding signal switched on is.

The invention will now be explained in more detail with reference to FIGS. only the parts necessary to understand the invention are shown. Identical parts that can be seen in the figures are provided with the same reference numerals. The figures show: FIG. 1 a circuit arrangement for increasing the edge steepness of pulses according to the invention, FIG. 2 shows an embodiment of the controllable according to the invention Amplitude discriminator in detail, Fig. 3 pulse diagrams in the circuit arrangements signals occurring according to FIGS. 1 and 2, FIG. 4 shows a further exemplary embodiment of the controllable amplitude discriminator according to the invention - in detail, Fig. 5 pulse diagrams the signals occurring in the circuit arrangements according to FIGS. 1 and 4, FIG. 6 a further circuit arrangement for the edge steepening of pulses according to FIG Invention, FIG. 7, pulse diagrams of those occurring in the Sohaltungsanordnung nao Fig. 6 Signals.

in the circuit arrangement according to FIG. 1, the terminal 1 is supplied Impulse becomes an impulse through the pass filter 2 (e.g. transmission line) A (see FIG. 3 or FIG. 5 with flattened edges and overshoots distorted. To increase the edge, this pulse A receives a correction signal in an adder 3 G 'added so that a signal 11 with steep at terminal 4-at the output of the adder stage Flanks arises. The correction signal G 'is doubled in a manner known per se Differentiation of signal A is generated. In the first pifferenzierstufe 6 a Signal II formed according to the first differential quotient of signal A. Then the signal 13 is fed to the controllable amplitude discriminator 7, in which the in signal II contained overshoots eliminated so that the signal F can be removed at its output. This signal F becomes is differentiated again in the second differentiating stage 8, whereby the signal G arises. By reversing the phase of the signal G in the phase reversing stage 9, the correction signal G 'generated. In order to determine the delay time difference between the signal to be corrected A and to compensate for the correction signal G ', the signal A becomes the delay before the addition passed through the term element ii.

The controllable amplitude discriminator according to the invention is shown in FIG 7 shown in detail. It essentially consists of two parallel branches each with a first cut-off stage 12 or 12 ', one each acting as a storage element Capacitor 13 or 13 ', one voltage divider 14, 15 or 14', 15r and one each second cut-off stage k6 or 16 ', the outputs of which are connected to an adder stage 17 are.

Furthermore, between the input of the amplitude discriminator 7 and the circuit point 18 or 18 'between storage element 13 or 13s and voltage divider 14, 15 or 14r, 15 'each have a Sohaltmare 19 or 1.9' connected.

The cut-off stages have a high input resistance and are adjusted so that the cut-off stages 12 and 16 only voltages above one certain potential and the cutoff stages 12 'and l6 only voltages below of a certain potential. This results in the cut-off stages at the outputs 12 and 12 'the signals C * or. C ', in which all signal components are below or above the cut-off potentials are cut off. With the voltage divider 14, 15 resp. 14 ', 15' a DC voltage can be added to the signal with which the signal can be changed in relation to the Absefineidepotentials. The capacitance of the capacitor 13 or 13 'is chosen so small that the time constants, which are caused by capacitor and voltage divider is formed, is about as large, never the time constant of the exponential function, with the dio overshoots of signal B decay.

To explain the mode of operation, the upper branch should first be considered been. Due to the positive voltage jump of the signal C, the coating a of the capacitor becomes 13 charged. The potential of the coating b of the capacitor 13, however, increases because of the small time constant is not proportional to the potential of the coating a, but will be delayed a little. The voltage drop across the capacitor 13 is therefore greater. At the beginning of the overshoot at the end of the positive pulse of the signal C becomes therefore the potential of the lining b is pressed below the zero line, so that the oscillations be cut off by the subsequent cutting stage 16. How far the potential of the lining b is pressed below the zero line, depends on the size of the momentum of the signal C and the time constant of the capacitor 13 and the voltage divider i4, 15 from. The greater the impulse and thus also the overshoots, the more further the potential is pushed below the zero line. The dependency is exact proportional, so that the overshoot ou gene independent of the size of the pulse always been cut off. The Zcitkonstants of the EC member 13, 14, 15 is like this chosen so that the overshoots are just cut off reliably. This ensures that a positive voltage jump occurs immediately following further positive voltage jump the potential of the coating b of the capacitor 13 again rises above the zero line, so that also for this second voltage jump a correction signal of almost undiminished amplitude is generated.

The positive overshoots occurring after the negative voltage jumpon in signal C are suppressed by the fact that during the duration of the negative voltage jump the coating b of the capacitor 13 is brought to a negative potential.

This gives the capacitor 13 a jump proportional to the negative jump additional voltage drop of the subsequent overshoots below the cut-off potential that of the cutoff level 16 pushes down. Dios is with the switching step 19 reached, which is controlled by the output of the first differential stage 6. The switch 19, which responds only to negative voltage jumps, pulls during this Voltage jump a positive current surge from the coating b of the capacitor 13, whose Amplitude is approximately proportional to the amplitude of the controlling voltage. As a result, the coating b of the capacitor 13 is brought to negative potential, see above that a signal D arises at the input of the second cut-off stage 16. To that too to suppress positive overshoots present from the negative voltage jump, is between the first differentiation stage 6 and the cut-off stages 12 or l22 Delay element 21 switched, while the switching stages 19 and 19 'immediately on Output of the first differentiating stage 6 lie. The signal D- is over the second Cut-off stage 16 passed so that a signal E is produced at the output of stage 16. Thus, the upper branch only leaves those associated with positive voltage jumps positive pulses of the signal corresponding to the first differential quotient pass, while negative pulses and all overshoots are suppressed.

Accordingly, the lower branch only allows voltage jumps that are too negative associated negative impulses of the corresponding to the first differential quotient Passisren signal while positive pulses and suppresses all overshoots will. The lower branch operates in the same way as the upper branch Branch. The signals generated at the output of the upper and lower branch E and Et are fed to the adder 17, at the output of which the signal F can be taken off is.

The correction signal obtained in this way can be used for some applications G 'still be too wide. A narrower correction signal N according to FIG. 5) can be used with With the aid of the controllable amplitude discriminator 7 'shown in FIG. 4 obtained will. This controllable amplitude discriminator 7 'contains two further switching | stages 22 or 22, which via a phase reversing stage 23 to the output of the first differentiating stage 6 are connected. The further switching stage 22 speaks because of the upstream phase | reversing stage 23 to positive voltage jumps at the output of the differentiating stage 6, so that the capacitor i3 already before the positive pulse over the delay element 21 arrives, receives an additional voltage drop that partially affects the pulse below the separation potential of the subsequent cut-off stage 16. A signal K therefore arises at circuit point i8 (FIG. 5). Daduroh becomes the impulse of the signal K cut off further above. The pulse of the signal L or L 'is therefore narrower than the pulse of the signal E or E. This also makes that of the second Signal N corresponding to the differential quotient is narrower, and thus also the correction signal Nt. With a voltage divider connected to the output of the phase reversing stage 23 (not shown) is a continuous adjustment of the width of the correction signal possible.

Another possibility to generate a narrower correction signal, will now be explained with reference to FIGS. 6 and 7.

here the once differentiated signal B becomes a controllable one Amplitude discriminator 71 corresponding to that shown in Figure 2, but only with the parts contained up to the dash-dotted line 24, i.e. without the adder stage i7, supplied. The removable at the output of the controllable amplitude discriminator 71 Signals E, E 'are fed to the second differentiating stages 8, 8 ″, at whose outputs the Signals P and P 'can be measured. These signals are sent to the cutoff stage 26 or 26t, at the outputs of which the signals lt and R 'can be taken off. These signals are put together in the adder 17 '. At the output of the adder 17t is The signal S, which is fed to the third differentiating stage 27, can be removed. The signal T corresponding to the third differential quotient of the signal A becomes a phase reversing stage 9, at the output of which the correction signal can be removed is. This correction signal is added to signal A in adder 3, so that At the output of the adder a at terminal 4, a signal U with steep edges can be removed is.

Claims (3)

Claims 1. Circuit arrangement for generating a correction signal for the Edge steepening of pulses by adding differentiated signal components of the input signal, consisting of the series connection of a first differentiating stage to form a corresponding to the first differential quotient of the input signal Signals, an amplitude discriminator to suppress signal overshoots, a second differentiating stage for forming one of the second differential quotients of the input signal and an adding stage for adding the Correction signal formed in this way for the input signal, characterized in that the Amplitude discriminator (7.7t) made up of two parallel branches, each with a first cut-off stage (12 or 12t), a storage element (13 or: 13t), a voltage divider (14, 15 or 14 ', i5') and a r second cut-off stage (i6 or 16t) that between Storage element (13 or 13t) and voltage divider (14, 15 or 14 ', 15') of the output each a switching stage (19 or 19 ') is connected, which with one of the first Differential quotient of the input signal corresponding signal (B) controlled and that the two parallel branches each have an input of an adder stage (17) are connected. 2. Circuit arrangement according to claim 1, characterized in that the amplitude discriminator (7 ') contains two further switching stages (22 or 22'), which via a phase reversal stage (13) with a first differential quotient of the input signal corresponding signal (B). are controlled, and their respective Output connected to the corresponding output of the first switching stage (19 or 19 ') are. 3. Circuit arrangement according to claim 1, characterized in that between the second differentiating stage (8 ', 8 ") and the adding stage (3) a third Cut-off point (26 or 26 ') urO a third differentiation stage (27) for forming a corresponding to the third differential quotient of the input signal Signal (T) is included.