DE1221689B - Electronic pulse correction circuit for telecommunications, in particular telephone dialing systems - Google Patents

Description

Electronic pulse correction circuit for telecommunication, in particular Telephone dialing systems The invention relates to a circuit arrangement for electronic pulse correction in telecommunications systems, in particular telephone dialing systems, in which switching orders are transmitted in the form of pulses, in particular pulse series will.

The ones in telecommunication systems from the number switch of a telephone set Incoming impulses show as a result of the between the subscriber set and that of this to be controlled circuit device lying connecting lines distortions on. For the safe setting of the voters etc., however, the individual Current surges have a certain ratio of current flow to current interruption, so be as distortion-free as possible. That's why there is one at the next end of each Management facilities for correcting the pulses to the correct pulse ratio necessary.

There are already circuit arrangements for improving current surges or current impulse series known that work with equalization relays. Also known is a circuit arrangement for pulse shaping by means of transistors, in which a Desired pulse train from a given pulse train with the same pulse repetition frequency is derived. In this circuit arrangement, however, it is disadvantageous that it only corrected output pulses from such uncorrected input pulses can form, which only have a greater width than the target output pulses.

The object of the invention is to provide an electronic correction circuit to create that replace electromechanical pulse correction circuits while doing so Both too short and too long pulses while maintaining the input pulse frequency can correct.

The circuit arrangement for electronic pulse correction is in accordance with the invention designed so that an element which is in the stable state of a first, from the rising edge of an input pulse to the unstable state controllable monostable multivibrator is low-resistance, together with another for the duration of an input pulse conductive element in the manner of an AND circuit the unloading path of a connected parallel to the input of a second monostable multivibrator Capacitor whose charging voltage swing triggers this flip-flop that also the Output of the element blocked in the stable state of this flip-flop with the input a third flip-flop is connected, the output potential of which falls back the second flip-flop in the stable state either for a specific Proper time or until the second tipping stage is again tilted into the unstable state assumes a second value, and that this third flip-flop is a switching transistor is connected downstream as a pulse output.

Advantages of this electronic pulse correction are among others the greater operational reliability compared to an electromechanical arrangement and the possibility of keeping smaller time tolerances in the formation of the output pulses to be able to. In addition, the electronic correction circuit can galvanically from the Official battery kept completely separate and therefore smaller with transistors Operating voltage can be operated.

It is also advantageous that this correction circuit is immediate connected or connected to the output of a tone dialing or out-of-band dialing receiver can be interconnected with this, so that the temporally imprecise alternating current characters immediately in direct current signals with the pulse-pause ratio required by the switching technology can be implemented. As a result, the effort required for the Achieving small character distortions in terms of amplification and linearity driven must be saved.

In the following, a preferred exemplary embodiment is illustrated using two figures the invention explained in more detail.

The electronic pulse correction shown improves individual pulses that are too short or too long or the pulse-pause ratio of pulse series to predefinable values if the total input time of a pulse, i.e. H. the time that corresponds to the duration of a pulse and its assigned pulse pause is between about 80 and 120 msec. The input pulses are each inverted.

The circuit ( Fig. 1) is essentially divided into the three parts I, II and 111. The input part I has two input terminals E1 and E2. If pulses with a negative potential need to be corrected, these must be fed to input E 1 . Positive pulses must be fed to input E 2. The transistor T1, which is conductive in the idle state, is blocked by a positive pulse, as a result of which a negatively directed signal appears at point A. The rest of the way is the same for both the positive and negative pulses: They each control transistor T4 to the low-resistance state. The transistor T4, which is blocked in the quiescent state, forms, together with the transistor T 3, which belongs to the monostable multivibrator consisting of the two transistors T2 and T3 and which is conductive in the stable state of this multivibrator, a discharge path for the capacitor C4 in the manner of an AND circuit. In the idle state of the circuit, the capacitor C4 is charged to the potential of the voltage rail -24V. If the transistor T4 is now controlled into the saturation range by an input pulse, that is to say switched through, then the point C takes over the charging potential of the capacitor C4. As a result, the transistor T 2 is also controlled into the pass band via the voltage divider R 2, R 3. As a result, the base of the transistor T3 receives a positive pulse almost simultaneously via the capacitor C 2 from the collector of the transistor T2, which pulse blocks the transistor T3. This blocking remains in effect until the capacitor C2 connected to the base of the transistor T3 has recharged sufficiently through the resistors R 6, R 7. The time constant of this arrangement is about 10 msec so that short interference pulses which make transistor T4 conductive also block transistor T3 for a period of 10 msec, so that the potential at point B is not influenced by an interference pulse <10 msec can be.

If, however, pulses arrive at inputs E1 or E2 whose base point width exceeds 10 ms, transistor T4 is still conductive when transistor T3 of the multivibrator in circuit section 1 also becomes conductive again. As a result, the capacitor C 4 will now discharge until the falling edge of an input pulse causes the transistor T4 to go back to the blocked state. The capacitor C 4 is now charged again via the -24V voltage rail. This charging process causes a short negative current surge flowing through the capacitor C5 to the base of the transistor T5. The transistor T 5 forms in circuit section II together with the transistor T6 a second monostable multivibrator with a defined time constant determined essentially by the resistors R 15, R 16 and the capacitor C 6. In the stable state of this trigger stage, the transistor T6 has current flowing through it and the transistor T5 is blocked. Due to the pulse that now controls transistor T 5 from capacitor C 5 , transistor T 6 is blocked via capacitor C 6. The potential of point D, i.e. H. the output potential of the transistor T5 influences a further transistor T7 via the resistors R 20, R 21. This transistor is conductive when the circuit arrangement is idle, as is the transistor T8, the base of which is connected to the collector of the transistor T 7 via the capacitor C 8 . The falling edge of an input pulse, which blocks the transistor T 4 and switches on the transistor T 5 , causes, via the potential jump at point D, that the transistor T 7 changes to the blocked state. When, after the unstable state has elapsed, the flip-flop of circuit section II returns to the stable state, the potential of point D jumps back to a larger negative value. The transistor T7 is thereby switched through again, and a positive pulse now reaches the base of the transistor T8 via the capacitor C8, which is consequently blocked. The potential of the point F is thereby shifted into the negative in such a way that the switching transistor T 9 is turned on via the voltage divider R 26 + R 27 / R 25. In the output circuit of the transistor T9 is z. B. the pulse relay J is arranged, which now picks up and actuates its contact i located in output A 'or applies a positive signal to electronic output A (T9) .

When the capacitor C 8 is charged again via the resistors R22, R23, so the base of the transistor T8 is again negative against the emitter of this transistor, the transistor T 8 opens and thus blocks the transistor T 9. The relay J is de-energized and whose contact i returns to the rest position. The time constant of the flip-flop (differentiating element) of circuit section III, which can be adjusted with the aid of the resistor R 23 designed as a potentiometer, is now dimensioned so that a pulse of 60 msec duration is emitted at the pulse output.

This process is repeated with every further pulse arriving via inputs E1 or E2. If the falling edge of the next pulse reaches transistor T4 within a period of a little more than 40 to about 100 msec after the falling edge of the previous pulse, the trigger stage of circuit section II is again thrown into the unstable state, i.e. That is, the transistor T5 becomes conductive, whereby the transistor T7 is blocked via the potential of the circuit point D. A negative voltage surge now reaches transistor T8 via capacitor C 8 and opens it prematurely.

Individual pulses that exceed a duration of 10 msec are thus lengthened to 60 msec by the circuit arrangement or, if they are longer than 60 msec, shortened to 60 msec. Occur at the inputs El and E2 pulse series, so is the * respective Impusl pause total time at the input determinative of the total time at the output, d. i.e. the pulse repetition rate is retained. If the total input pulse time is z. B. 80 msec, then an output pulse of 40 msec is emitted, and the output pulse ratio is then equal to 1: 1. If the total input pulse times are greater than 100 msec, z. B. equal to 110 msee, then pulses of 50 msec duration appear at the output, and the pause times are then 60 msee.

FIG. 2 shows the relationship between the total input pulse time T shown in FIG . 2 is plotted as the ordinate value of the graphic representation, and the output pulse times or output pulse pause times a and b. One draws in one's mind z. B. at a total input pulse time of 110 msee a horizontal straight line to the respective intersection points with the lines b and a and then goes from these intersection points vertically downwards, then z. B. at a total input pulse time T equal to 110 msec, an output pulse duration of 60 msec and an output pulse pause time of 50 msec can be read.

By changing the time constants in the individual flip-flops, the dependence of the pulse-pause ratios of the output pulses on the total input pulse times influenced and the period of time within the glitches are suppressed, increased or be reduced in size.

In the third trigger stage, the capacitor C 8 which connects the collector of the transistor T7 to the base of the transistor T8 and through which the pulses that block the transistor T8 run is bridged by a Zener diode Z 4. The Zener diode has the effect that pulses which exceed a certain value corresponding to the Zener voltage of the diode are short-circuited. This prevents impermissibly high voltages from occurring at the collector-base path of the transistor T8. At the same time, the Zener diode serves as a current path in the forward direction, via which an additional current flows when the transistor T7 is switched over. This current shortens the time required to recharge the amounts of charge stored in transistor T7 (relaxation time).

Claims (2)

1. A circuit arrangement for electronic pulse correction in telecommunication systems, in particular Fernsprechwählanlagen in which switching orders in the form of pulses, in particular pulse trains, are transmitted, d a d u rch g e - denotes that an element (T3), which in the stable state of a first , from the rising edge of an input pulse in the unstable state controllable monostable multivibrator (T2-T3) is low, together with another element (T4) that conducts the duration of an input pulse in the manner of an AND circuit, the discharge path of one of the input of a second monostable multivibrator (T5-T6) parallel-connected capacitor (C4), whose charging voltage swing triggers this flip-flop, that furthermore the output of the element (T5) blocked in the stable state of this flip-flop is connected to the input of a third flip-flop (T7-T8), the output potential of which is at The second flip-flop level falls back into the stable state in each case either for a certain time or until the second flip-flop is again tilted into the unstable state, and that this third flip-flop is followed by a switching transistor (T9) as a pulse output. 2. Circuit arrangement according to claim 1, characterized in that the low-resistance element in the stable state of the first monostable multivibrator is a transistor (T3) which at the same time forms one of the two active elements of the first monostable multivibrator. 3. A circuit arrangement according to claim 1 or 2, with the transistors in the third flip-flop, characterized in 'that in the third flip-flop, a denKollektor of connecting a (T7) with the base of the other active Kippstufentransistors (T8) capacitor (by a Zener diode Z4 (C 8) ) is bridged in such a way that on the one hand the switching pulses reaching the base are limited to a defined value, on the other hand a current flowing through the Zener diode in the forward direction shortens the relaxation time of one transistor. 4. Circuit arrangement according to spoke 1 to 3, characterized in that the correction circuit is preceded by a selective AC amplifier tuned to a predetermined signal frequency with a subsequent simple rectifier stage.