DE1075663B - Circuit arrangement for restoring the steepness of the edge of pulses and for increasing the power of pulses - Google Patents

Description

GERMAN

In pulse technology, especially on transmission lines for pulses, the task is often given to regenerate the impulses, d. H. i.e. from impulses with more or less smooth rise and falling edges again to form pulses that have a vertical rise and preferably also Have trailing edge. In particular, this task is given, for example, in the technology of telegraphy, for example whenever the telegraphing steps and after an alternating current transmission the demodulation of the alternating current pulses direct current steps are to be generated which are as approximated as possible are rectangular. As is known, when transmitting pulses with the help of alternating voltages or these pulses already flow on the alternating current side through the use of filters etc. so sharply polished in the flanks that after demodulation, i.e. after conversion into direct current pulses, only more or less trapezoidal impulses arise. For a clear evaluation of the telegraphing steps, however, pulses that are as rectangular as possible must be available. For these square pulses there is also the requirement that they must have a certain energy content.

For the tasks mentioned, especially for the regeneration of trapezoidal impulses into rectangular ones Pulses are usually used as monostable or bistable multivibrators change their state abruptly when exceeding or falling below certain voltage values, so that the output voltage taken from these flip-flops also changes its value abruptly. Such a circuit arrangement is, for example, also the known multi-circuit circuit. This exists from an amplifier system equipped with positive feedback such that the when the circuit responds, the feedback voltage has the effect of controlling the control voltage supports. So that this circuit arrangement at a very specific voltage value is triggered, is in the control line, directly in front of the control electrode, a direction-dependent Resistance, e.g. B. a diode arranged.

The principle of a multi-circuit circuit is explained below with reference to FIG. 1, a conventional flat transistor TV1 being used as the amplifier system. The circuit arrangement receives its control voltage via the input B. The control input is led to the base via the primary winding of the transformer U, the secondary winding of which is in the collector line of the transistor. The directional conductor Gl is connected upstream of the entrance. The voltage is supplied on the collector side via the resistor R2 and on the base via the resistor R 1. The off circuit arrangement

to restore

the steepness of the pulse edge

and for performance enhancement

of impulses

Applicant:
Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Witteisbacherplatz 2

Dr. phil. Abund Wist, Munich,
has been named as the inventor

output voltage can be taken from terminal y4 will.

The function of the circuit is based on the fact that as long as the voltage at the input E is strongly negative, the directional conductor G 1 is blocked, so that the transistor, whose base is correspondingly biased via the resistor R 1, carries current. If the voltage at input B rises in a positive direction, a point is reached at which the resistance of the directional conductor G 1 is already so low that it no longer represents an interruption of the positive feedback. At this point in time, however, the resistance of the directional conductor is still so great that the potential of the base cannot be raised far enough. At this point in time, the circuit behaves like a normal blocking oscillator, ie square-wave oscillations occur whose frequency is dependent not only on the general dimensioning of the circuit but also on the base potential of the transistor. If the voltage at the input continues to rise in a positive direction, the directional conductor opens completely and the base potential shifts so far that the transistor is blocked. The same conditions apply analogously to the reverse voltage cycle at the input, ie after the voltage has dropped to negative by a certain amount, the transistor is opened again.

As the explanations show, the circuit works properly when the voltage at the input is between the value at which the directional conductor G 1 is just opened and the value at which this directional conductor is fully controlled in one

909 730/316

3 4

Period of time is passed through which is smaller than the very far increase when the characteristic curve of the time constant used in the feedback circuit, so that the directional conductor is particularly clearly kinked.
Arrangement cannot oscillate in this case. In many cases, the flip-flop switch should be used, in this case a clearly working monoton to control a relay, a stable flip-flop circuit which, in a known manner, can result in a very specific voltage value at the input cause a bistable relay to take on both of its states. At the output there are windings in the two collector leads of the clear square waves, since depending on the transistors Tr 1 and Tr 2 are switched on. Whether the transistor TrI is conductive or not, it is because of constructional reasons that a large or small voltage is dropped here, especially on board R2. ok part, on the core of the relay also the same

If, on the other hand, the critical voltage range only slows down the feedback winding for the multi-input run through, then the circuit swings, spend.

and the initial potential is no longer unambiguous. FIG. 3 shows a representation according to FIG. 2

This is, as stated above, for. B. with output corresponding circuit design, but with the

circuits in telegraph equipment extremely annoying, since the difference is that the collector leads to the two

this can result in false tripping. the transistors across the two windings of one

The invention relates to a circuit bistable relay SR are performed. The feedback arrangement with which the oscillation of a multi-winding is as an additional winding on the core circuit can also be suppressed when the relay is attached.

the rise in the control voltage is very flat. 20 In the case of the one described with reference to FIGS. 2 and 3

Conversely, in the case of the circuit arrangement according to arrangements, a single

the invention, the advantages of a multi-circuit, the current are converted into a double current, wherein

i.a. known in the high sensitivity with the circuit arrangement even, as shown,

Voltage changes lie, fully utilized. This an output relay can be operated. The presented

is achieved according to the invention in that the adjusted arrangement still has the disadvantage that

Stronger element of a multi-function circuit with sufficient sensitivity, which is

Switching element can be achieved in the manner of a multivibrator circuit drigung the supply voltage

is coupled in such a way that the tendency of the can to oscillate, the output of the flip-flop is so small,

Multiars is suppressed. that they may be used to exercise a

According to a further development of the concept of the invention, there is no longer any specific power requirement

kens, this can be achieved particularly simply by being sufficient.

be that the additional amplifier- According to a development of the inventive concept

element derived voltage at the input kens can also avoid this disadvantage.

The bias voltage repre- sentations that lie in the multi-circuit circuit are that by the from the multi-circuit circuit

stand is created. 35 and the additional amplifier element existing

The circuit arrangement according to the invention as well as the trigger circuit is controlled by a further flip-flop,

advantageous details are given on the basis of the

Fig. 2 and 3 circuit designs shown in the device in relation to that of a relay is low, can

explained below: the sensitivity of the first toggle switch fully

In Fig. 2, an arrangement is shown at 40 are constantly used.

in the left part a multi-circuit according to FIG. 1. FIG. 4 shows an exemplary embodiment in this regard. Which is reproduced, which according to the invention to a trip circuit in turn consists of the transistor Tr 2 in the manner of a bistable Kippschal- TrI containing multi-circuit, which is expanded like the Antung. The order according to the invention as shown in FIG. 2 by a second transistor task, the oscillation of the multi-circuit at 45 Tr 2 is supplemented in the manner of a multi-vibrator circuit, to prevent application of a certain voltage, in addition, in the connecting line between the coupling resistor i? 3 reached, through which the two emitters a resistor Th with negative the supply voltage is switched on at the base of the transistor temperature coefficient. Depending on Tr 1 when the multi-circuit triggers the position of this trip circuit, a second breakover is gated. Depending on whether the applied voltage is 50 circuit, which is composed of the two transistors Tr 3 at the upper or lower edge of the oscillation range and Tr 4, among other things, controlled. The entire double is, the transistor Tr 2 is opened or the flip-flop circuit works as a monostable flip-flop circuit blocks and thus the multi-circuit circuit is blocked or in the same way as the trip circuit itself. To be fair. The circuit arrangement shown shows a perfectly monostable function of this Dop and shows certain similarities with a normal double flip-flop, it is advantageous to use the stable flip-flop. In contrast to one of the coupling resistors between the individual transistor-like circuits, however, as mentioned, it can be paired with the resistors WX and W 3, fFlQ with arbitrarily flattened voltage pulses and fF "14, W 12 and W16 to become highly asymmetrical, while flip-flops, making par-. to the asymmetry of the circuit to Errei particular when they are constructed from transistors, chen 60, the individual collector resistors of very steep voltage pulses are to be controlled transistors 7V3 and Tr 4 is divided (W12 and W 13 must, if the tilting or PFlound is working properly fF17).

circuit should be guaranteed. When the transistor 7> 2 is blocked, the base current voltage will reverse its sign in the illustrated embodiment of this transistor. This current is taken from the collector of transistor 7V2. 65 reversal leads to a voltage drop at the base - you can of course just as well from the collector resistance W6. When the current increases, the transistor TrI in particular is removed. those at higher temperatures, those at this

The sensitivity of the illustrated arrangement resistance dropping voltage will be so great that

the transistor TV2 can no longer remain blocked by increasing the resistor R3. Around

and lowering the supply voltages then 70 to achieve a clear blocking, it is necessary

dig to bias the emitter of transistor Tr 2 very strongly negative. According to the illustrated embodiment, this is achieved in that the emitter is connected to the connection point between the two resistors JV & and WS .

As long as there is no voltage or a very negative voltage at the input of the entire circuit arrangement, as at the input of the multi-circuit, the transistor Tr 1 carries current. As a result, the transistor Tr 2 is blocked via the resistor W 3, ίο · In addition, the transistor Tr 3 is blocked because of the small negative collector potential at the transistor Tr 1, which makes the base potential of the transistor Tr 3 more negative than its emitter voltage. The collector potential of this transistor is thus very negative, so that the transistor Tr 4 is opened. On keying of the transistor Tr 4 is supported not by the state of the transistor Tr 2, since Tr 2 a large negative collector voltage occurs at this transistor, on the other hand, the relatively small ao collector voltage of the transistor Tr 4, the small per se negative collector voltage of the transistor Tr 1 shifts even more into the negative range and thereby keeps the transistor Tr 2 safely in the restricted area. If a slowly increasing voltage is applied to the input, the voltage at the collector of the transistor Tr 1 shifts into the negative range until the transistor Tr 2 is opened via the resistor Wi. By this Potentialveiiagerung at the collector of the transistor Tr 1 and ■ the opposite potential shift at the collector of the transistor Tr 2, the transistor Tr 3 is opened and the transistor 4 is blocked, whereby this switching is supported between the two transistors through resistors Wil and W 15th Similar considerations apply to the tilt back process. The mutual influence of one transistor by the other three results in a great stability of the circuit arrangement.

5 shows that according to the invention it is advantageously also possible with the aid of a second Diode and an additional feedback winding create a bistable multivibrator with two equivalent Build inputs that are just as sensitive as the monostable explained with reference to FIGS. 2 to 4 Flip-flops. The circuit arrangement is otherwise constructed analogously to the arrangement according to FIG and also works accordingly.

The two inputs of the bistable multivibrator can be combined, namely recommends ■ it is, provided the circuit arrangement with double current symbols is to be controlled, a summary according to FIG. 6, that is, using a Potentiometer to make, at whose tap the center potential, preferably the ground connection of the Toggle switch is placed. The use of a • potentiometer results in a dual current input with simple balancing option.

FIG. 7 shows a possible embodiment for combining the two inputs of a bista part Flip-flop circuit according to FIG. 5, which is then advantageously selected when the circuit arrangement as Wants to use frequency divider stage.

FIG. 8 shows an advantageous further development of a double current input circuit explained with reference to FIG. 6. In the illustrated embodiment, a double potentiometer DP is provided, the taps of which are used to supply an adjustable bias voltage to the two inputs via two directional conductors G 2 and G 3. The type of potentiometer connection allows the response values of the flip-flop to be changed as required.

When explaining the mode of operation, it was assumed that the circuit as a voltage indicator Should be used. Of course, with the help of an appropriately chosen Bias the circuit can also be used without modification as a very sensitive zero indicator. The invention can also be implemented in other ways than explained. In particular, it is possible build the circuit arrangement from npn transistors and not, as shown, from pnp transistors. In this case, the potentials of the supply and control voltages are reversed accordingly around. Of course, the entire circuit arrangement can also be constructed from tubes. Even in this case the circuit arrangement is particularly sensitive.

When using a further flip-flop as a direct current amplifier element, it is, as explained, special advantageous, the feedback for the multi-input from the collector circuit of the second flip-flop decrease, because in this collector circuit there is usually at least one relay winding is arranged, from which this voltage can be tapped directly inductively, without additional a transformer would have to be provided. Of course, the feedback voltage for the multi-input can also be taken from the collector circuit of a transistor in the tripping stage. In this case, even a somewhat greater sensitivity of the circuit arrangement is achieved, however This higher sensitivity necessitates the additional expense of an additional transformer.

Claims (12)

PATENT CLAIMS: 1. A circuit arrangement for restoring the edge steepness and for the power amplification of pulses, characterized in that the amplifier element (TrT) of a multiarcircuit with a second amplifier element (Tr 2) is coupled in the manner of a multivibrator circuit in such a way that the tendency of the multivibrator to oscillate is suppressed when the control voltage rises slightly will. 2. Circuit arrangement according to claim 1, characterized in that the voltage derived from the additional amplifier element (TV 2) is applied via a resistor (R3) to the input of the multi-circuit (control electrode of the feedback amplifier element TrI). 3. Circuit arrangement according to claim 1 and 2, characterized in that one winding of a bistable relay (telegraph relay) is switched on in the collector circuit of the transistor (TrI) and the additional transistor (Tr 2) contained in the multiar circuit and that the feedback voltage of the multiar is tapped inductively from one of these windings. 4. Circuit arrangement according to claim 1 to 3, characterized in that a further flip-flop & (Tr 3 and Tr 4) is controlled by the trip circuit consisting of Multiar and an additional amplifier element. 5. Circuit arrangement according to claim. 4, characterized in that the supply voltages for the trip circuit (TrI and Tr 2) of the additional flip-flop (Tr 3 and Tr 4) can be derived. 6. Circuit arrangement according to claim 4 and 5, characterized in that the supply voltage for the multiar and the additional amplifier element via two different resistors (WlO and W 14) are derived from the two base voltages of the additional flip-flop so that the arrangement can oscillate safely is avoided. 7. Circuit arrangement according to claim 4 to 6, characterized in that the windings of the bistable relays (telegraph relays) arranged in the collector circuits of the additional flip-flop are. 8. Circuit arrangement according to claim 7, characterized in that the feedback winding with the in the additional flip-flop arranged windings of the bistable relay is coupled. 9. Circuit arrangement according to claim 1 to 8, characterized in that the tripping stage (Tr 1 and Tr 2) is constructed symmetrically in that a feedback winding input is connected to the base of the additional transistor (Tr 2). 10. Circuit arrangement according to claim 9, characterized in that when activated the two inputs are connected to one another via a potentiometer with a double current symbol, whose tap is at the intermediate potential, preferably ground, of the double flip-flop circuit. 11. Circuit arrangement according to claim 9, characterized in that when controlled with single current characters the two inputs are directly connected to each other. 12. Circuit arrangement according to claim 1 to 11, characterized in that between the two A resistor with a negative temperature coefficient is switched on at the emitters of the tripping stage is. Considered publications:
British Patent No. 583 553. 1 sheet of drawings