DE2114149C3 - Amphtude discriminator for a circuit arrangement for generating a correction signal for flank adjustment of pulses - Google Patents

Description

The invention relates to an amplitude discriminator for a circuit arrangement for generation a correction signal for increasing the edge of pulses by adding differentiated signal components of the input signal, which is formed from the series connection of a first differentiating stage a signal corresponding to the first differential quotient of the input signal, the amplitude discriminator to suppress signal overshoots, a second differentiating stage for Formation of a signal corresponding to the second differential quotient of the input signal and a Adding stage for adding the correction signal thus formed to the input signal.

In known circuit arrangements of this type, this causes overshoots in the correction signal suppresses that the amplitude discriminator connected between the first and second differentiating stage only the positive and negative peaks of the corresponding to the first differential quotient

lets the signal through. 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 the

largest occurring pulse jumps the signal overshoots in the first differential quotient corresponding signal can be suppressed. But that means that with small pulse jumps that the signal corresponding to the first differential quotient is completely suppressed. There is another disadvantage in the amplitude dependence of this circuit. When the threshold voltage is reached, it increases the amplitude of the signal corresponding to the first differential quotient of the input signal behind

as the «amplitude discriminator stronger to a!» the amplitude of the pulse jump. As a result, in the case of large pulse jumps, the correction signal is so large that it appears disturbing.

The object of the invention is to provide a circuit

Order to generate a correction signal for the steepening of the pulse edge by adding of differentiated signal components of the input signal, for which the amplitude of the correction signal proportional to the amplitude of the Im

is pulse jump, with overshoots being suppressed in the correction signal at the same time.

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

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

The amplitude discriminator expediently contains two for further steepening of the edge further switching stages, which have a phase reversal stage with one of the first differential quotients of the input signal corresponding signal can be controlled, and their respective output with is connected to the corresponding output of the first switching stage. Another possibility for flank steepening consists in that between the second cut-off stages and the further adder stage a second differentiating stage and a third cutting stage are switched on and that the output the further adding stage via a third differentiating stage to form a third differential

tialquotienien of the input signal corresponding fen 12 'and 16' only allow voltages below a certain potential connected to the input of the adder to pass. This results in, st the outputs of the cutoff stages 12 ^or - ¹ ^

The invention will now be explained with reference to FIGS. 1 to 7 the signals C or C, in which all Signaiamei e

explained in more detail, with only those for understanding of FIG. 5 below or above the cut-off potentials

Invention necessary parts are shown. Are cut off. With the voltage divider 14, 15

Identical teas evident in the figures are with the same or 14 ', 15' can be a direct voltage to the bignai

the reference numerals. It shows to be added with the signal in relation to the

F i g. 1 a circuit arrangement for Flankenver- Abschneidepotentiaie can be changed. the

control of pulses according to the invention, i = capacitance of capacitors 13 and 13, respectively

FIG. 2 an embodiment of the small chosen according to the invention, 'that the time constant, which durcn

MAESS controllable amplitude discriminator is formed in the capacitor and voltage divider, for example

Detail as large as the time constant of the exponential function, with

F i g. 3 pulse diagrams showing the overshoots of signal B in the circuit changes

Orders of Fig. 1 and 2 occurring signals, 15 To explain the mode of operation should first

F i g. 4 a further embodiment of the invention the upper branch can be considered. Due to the posi-

according to the controllable amplitude discriminative voltage jump of the signal C, the loading

tor in detail, la _{ga of} the capacitor 13 charged. The potential

Fig. 5 pulse diagrams in the circuit of the coating b of the capacitor increases because of

Orders of Fig. 1 and 4 occurring signals. 20 of the small time constant is not proportional to the

6 shows a further circuit arrangement for the potential of the coating α. but is somewhat delayed

Edge steepening of pulses according to the inventor. The voltage drop across the capacitor U

manure. So it gets bigger. At the beginning of the overflow

Fig. 7 pulse diagrams in the circuit at the end of the positive pulse of the signa sC

Order according to fig. 6 occurring signals. ^ 25 hence the potential of the surface b below the zero lime

One in the circuit arrangement according to FIG. 1 of the pressed so that the overshoots of the

The pulse supplied to terminal 1 is cut off by the downstream cut-off stage 16

pass "Hed2 (e.g. transmission path) to an Im-. How far is the potential of the covering /? below

pulse Λ (see Fig. 3 or 5) with flattened edges the zero line is printed depends on the oroise and distorted overshoots. For the edge crossing of the pulse of the signal C as well as of the time conversion, this pulse A is in an adder 3 constant of the capacitor 13 and the voltage divider

Iering is this pulse A in an adder 3 constant of the capacitor 13 and the pg a correction signal G ' added, so that on terminal 4 14. 15 from. The larger the impulse and thus also the signal H with steep overshoots at the output of the adder, the further the foil flanks will develop. The correction signal C is printed in an tial below the zero line. The dependence, as is well known, through two differentials is precisely proportional, so that the overshoots of signal A are generated. In the first differentiation, regardless of the size of the pulse, always aostutc 6, a signal B will be cut according to the first. The time constant of the Ki-uiil dilferential quotient of signal A is formed. Therefore 13, 14, 15 w <ύ selected so that the overshoot, the signal β is still reliably cut off to the controllable amplitude, in which the in the south. This ensures that any overshoots contained in pogna B are eliminated immediately following a voltage jump, so that at its output the signal F of the decreasing positive voltage jump is the potential of the bar. This signal F is used in the second differential coating /? of the capacitor 13 again tiner au. Zierstufe 8 differentiated again, whereby the Si zero line lifts out, so that there is also a negative for this one. By reversing the phase of the signal G. , 5 th voltage jump, a correction signal is almost unin the phase reversing stage 9, the correction signal of reduced amplitude is generated. C generated. In order to compensate for the difference in transit time between the signal A to be corrected after the negative voltage jump and the positive overshoots in the signal C wcrsignal CV , which are corrected, the signal A before the is suppressed by adding to the delay via the delay element 11; o the negative voltage jump of the lining ft des. Capacitor 13 brought to a negative potential. In FIG. 2, the controllable device according to the invention is shown. As a result, the capacitor 13 is shown in detail by an amplitude discriminator 7. The negative jump proportional additional ^ pan consists essentially of two parallel branches voltage drop which the subsequent overshoots with a first cut-off stage 12 or 12 ', each 55 gene below the cut-off potential of the Abscnneiuceinem acting as a storage element capacitor 1 stage 16 down. This is done with the bcnaitsiuit or 13 '. a voltage divider 14, 15 or 14 ', 19 is achieved, which is controlled by the output of the first Diiie-15' and a second cut-off stage 16 or renzieiMufeo. Are ^{the only "e aut. 1} ^ 16 'whose outputs responsive to an adder 17 reasonable voltage jumps switch \ f ziem closed. Further, between the input of the 60 during this voltage jump a positive amplitude discriminator 7 and the circuitry surge from the coating b of the Capacitor 1.5, whose point 18 or 18 'between storage element 13 or amplitude is approximately proportional to Ampii-13' and voltage divider 14, 15 or 14 ', 15' each a tude of the controlling voltage. 19 'connected. lining b of the capacitor 13 to a negative potential, the cut-off levels have a high input fi _S placed, so that at the input of the second ADscnncißanÄSwiderstand and are set so that the exhaust destufe 16 a signal D is formed. to the front of cutting stages 12 and 16 to suppress only voltages above the negative voltage jump, positive of a certain potential and the cut-off overshoot, is z know

first differentiating stage 6 and the cutoff stages 12 and 12 ', a delay element 21 is connected, while the switching stages 19 and 19' are located directly at the output of the first differentiating stage 6. The Signa! D is passed through the second cut-off stage 16, so that a signal E is produced at the output of this stage 16. Thus, the upper branch only allows the positive pulses of the signal corresponding to the first differential quotient belonging to positive voltage jumps to pass, while negative pulses and all overshoots are suppressed.

Correspondingly, the lower branch allows only the negative pulses of the signal corresponding to the first differential quotient belonging to negative voltage jumps to pass, while positive pulses and all overshoots are suppressed. The operation of the lower branch is the same as that of the upper branch. The signals E and E ′ arising at the output of the upper and lower branches are fed to the adder 17. at the output of which the signal F can be removed.

The correction signal G 'obtained in this way can still be too wide for some application purposes. A narrower correction signal (/ V according to FIG. 5) can be obtained with the aid of the controllable amplitude discriminator T shown in FIG. This controllable amplitude discriminator T contains two further sound stages 22 and 22 ', which are connected to the output of the first differentiating stage 6 via a phase reversal stage 23. The other Schaltslufc 22 responds to positive voltage jumps at the output of the differentiating stage 6 because of the upstream phase reversal stage 23, so that the capacitor 13 receives an additional voltage drop even before the positive pulse arrives at the transit time glicd 21, which partially drops the pulse below the cut-off potential of the following Cut-off step 16 is pressed down. A signal K is therefore produced at the circuit point 18 (FIG. 5). As a result, the pulse of the signal K is cut off further up. The pulse of the signal L or L ' is therefore narrower than the pulse of the signal £ or E'. As a result, the signal N corresponding to the second differential quotient also becomes narrower, and thus also the correction signal N '. With one at the exit

ίο the phase reversal stage 23 connected voltage divider (not shown) a continuous setting of the width of the correction signal is possible.

Another possibility of generating a narrower correction signal should now be based on FIG. 6 and 7 will be explained. Here, the once differentiated signal B is fed to a controllable amplitude discriminator 7 ″ corresponding to the one shown in FIG. Detachable signals E, E ' are fed to the second differentiating stages 8', 8 ", at the outputs of which the signals P and V can be picked up. These signals are fed to the cut-off stages 26 and 26 ', at whose outputs the signals R and R' respectively. These signals are combined in the adding stage 17 '. At the output of the adding unit 17', the signal 5 can be tapped, which is fed to the third differentiating stage 27. The signal T corresponding to the third differential quotient of the signal A is fed to a phase inversion stage 9, an whose output the correction signal] 7 "can be removed. This KorrckUirsignal is added in the adder 3 to the signal A , so that at the output of the adder 3 at terminal 4, a signal U with steep edges can be removed.

1 sheet of drawings

Claims (3)

Patent claims: 1. Amplitude discriminator for a circuit arrangement for generating a correction signal for increasing the edge of pulses by adding differentiated signal components of the input signal, which are derived from the series connection of a first differentiating stage to form a signal corresponding to the first differential quotient of the »input signal, the amplitude discriminator for suppressing signal overshoots, a second Differentiating stage for forming a signal corresponding to the second differential quotient of the input signal and an adding stage for adding the correction signal formed in this way to the input signal, characterized in that the amplitude discriminator (7, T) consists of two parallel branches, each with a first cutoff stage (12 or 12 '). a storage element (13 or 13 '), a voltage divider (14, 15 or 14', 15 ') and a second cut-off stage (16 or 16') that between the storage element (13 or 13 ') and voltage divider ( 14, 15 or 14 ', 15') the output of a switching stage (19 or 19 ') is connected, which are controlled with a signal (B) corresponding to the first differential quotient of the input signal, and that the two parallel branches each with are connected to an input of a further adder stage (17). 2. Amplitude discriminator according to claim 1, characterized by two further switching stages (22 or 22 ') which are controlled via a phase reversal stage (13) with a signal (B) corresponding to the first differential quotient of the input signal, and their respective output with the corresponding output the first switching stage (19 or 19 ') is connected. 3. amplitude discriminator according to claim 1, characterized in that between the second cut-off stages (16 or 16 ') and the further adding stage (17') each have a second differentiating stage (8 ', 8 ") and a third cut-off stage (26 or 26 ') are switched on and that the output of the further adding stage (17') is connected to the input of the adding stage (3) via a third differentiating stage (27) for forming a signal (T) corresponding to the third differential quotient of the input signal.