DE1088558B - Circuit arrangement for generating recurring pulse groups, in particular for sequence control in telecommunications systems - Google Patents

Description

GERMAN

The subject of patent application S 56779 Villa / 21a ³ (German Auslegeschrift 1057 661) is a circuit arrangement for generating recurring pulse groups, in particular for electronic call and signal machines, using a first multivibrator and at least one further multivibrator controlled by this, in which the outputs of the Multivibrators are led to the inputs of at least one coincidence circuit, the output or outputs of which are connected to one or one output each serving for the delivery of pulse groups and in which the duty cycle and the frequency component ratio of the or each controlled multivibrator are chosen so that the desired pulse groups can be faded out from the pulses supplied by the first multivibrator. With the aid of such a device, the call and signal signals to be supplied by a call and signal machine for telecommunication switching systems can be generated. For this purpose, the coincidence circuits are influenced in a very specific way by the multivibrators.

The invention shows a way how to create a circuit arrangement according to the main claim This patent application specified principle is constructed so that it can also be used for other telecommunications engineering purposes can be used. Multivibrators are also to be used for this purpose, which are to be connected together appropriately and to which the required coincidence circuits are to be connected. The intended use provided here is primarily the Sequence control in telecommunications switching systems. Such a circuit arrangement for generating recurring pulse groups using multivibrators, in which the outputs of the multivibrators via coincidence circuits delivering pulse groups at their outputs and at the duty cycle and the frequency division ratio of the multivibrators are chosen so that from the first multivibrator delivered pulses the desired pulse groups are hidden characterized in that the first multivibrator is externally controlled and without delay in both directions is reversible and that all further multivibrators controlled by this delayed from the rest position into the working position and can be reversed without delay from the working position to the rest position.

The further multivibrators controlled by the first multivibrator are advantageously shown in FIG a chain circuit composed of similar multivibrators, in which the input of each subsequent multivibrator with that output of the preceding multi-circuit arrangement to generate

recurring impulse groups,

especially for sequence control

in telecommunications systems

Addition to patent application S 56779 VIII a / 21a ³
(Interpretation document 1 057 661)

Applicant:

Siemens & Halske Aktiengesellschaft,
Berlin and Munich,

Munich 2, Wittelsbacherplatz 2

Dipl.-Ing. Otto Kneisel, Großhesselohe near Munich, has been named as the inventor

vibrators, which emits an output pulse as a pulse output with the same polarity as which has the pulse applied to its input. Coincidence circuits with two inputs can be used be provided with its controlling input to the one output pulse of the same polarity as the Input pulse emitting pulse output of a multivibrator, for example the controlled multivibrator, and with its controlled input to the likewise an output pulse of the same polarity as the pulse output of the next following multivibrator in the chain are connected. Furthermore, coincidence circuits with two inputs can also be provided, which with its one input to the one output pulse of the same polarity as the input pulse emitting Pulse output of a multivibrator and with its other input to the one output pulse opposite polarity as the input pulse emitting pulse output of the next in the chain other multivibrators are connected. The outputs of the following as blocking gates, Mixing gates and coincidence circuits, differently designated as coincidence gates, supply the pulse groups, which have to effect the sequence control of processes in telecommunications systems. Here can it be B. to control an electronic marker, its various Switching groups through the supplied pulses or

009 590/86

3 4

Pulse groups in the intended sequence and given voltage pulses have the

temporal entanglement brought to work the same temporal position.

will. In Fig. 2, among other things, the

Fig. 1 shows an example of a basic circuit where multivibrator outputs occurring pulse

the device according to the invention; 5 voltages shown. The curve ζ initially represents

FIG. 2 shows a diagram for the control voltage applied to the input s at this input and the

direction of occurring impulses and impulse groups; Curves al, al to el, e2 represent the

Fig. 3 shows an embodiment for a portion of the voltages in the multivibrator outputs

the basic circuit according to FIG. 1 using its time course. The at the outputs

of transistor flip-flops. IO of the multivibrators emitted voltage pulses

In the following, the invention will now be described with reference to the figures, each beginning at the relevant delay time. The 1 basic circuit of FIG. Later than the pulses in which each in the series contains the multivibrators M 1 to M 5. The foreign follow preceding multivibrator, and last, controlled multivibrator Ml is instantaneous, that is, to the S control voltage ζ at the entrance of the Multiwhen a suitable control voltage 15 vibrator Ml is switched off at its input ζ. Then all voltage is switched on, so it comes without delay from multivibrators at the same time back to its rest position of rest position in the working position, and when this returns, since no delay control voltage is switched off with this return, it returns and is effective.

also without delay, back to its rest position To generate certain impulses or impulse back. At its one output pulse of the same 20 groups, which are masked from the impulses emitted by the multivibrator Ml gelie polarity as the input pulse, blocking gates and coincidence gates are now, as already indicated at output al, the input of the multivibrator M2. This multivibrator is connected to the pulse outputs and inverting pulse outputs by the pulse span emitted by the multivibrator M1. Decoupling coincidences are also controlled. If the multivibrator Ml comes to the working position in the 25 circuits, so-called mixing gates, then the outputs may be provided on its pulse acquisition. In the circuit output al voltage such a level according to FIG. 1 are given some examples of the fact that the multivibrator MI is reversed in its working position coincidence gate, blocking gate and mixing gate. However, this only takes place with one of the here referred to as coincidence circuits. You take some time lag. The multi-30 can also respond in a different way than in the mentioned vibrator M 2, so to speak with a delay connected to the relevant outputs. When the multivibrator will be.

Ml resumes its rest position and therefore the voltage present at its pulse output c 1 is to be understood here as the following circuit arrangements: if the corresponding level, the multivibrator M2 returns 35 Rest position back. A certain output signal voltage occurs at its Im- when all pulse output b 1 now occur in its rest position at the same time a certain input and working position voltages of the same level are supplied to its inputs at the signal voltage. In the case of a mixing as at the output c 1 of the multivibrator M1 at its gate, a certain initial rest position and working position occurs at the output. At the output 62 of the 40 signal voltage, if at least one input multivibrator M 2 , the multivibrator M 3 is connected to its input with a certain input signal voltage supplied. He works the same way will. In the case of a blocking gate, one like the multivibrator M2 occurs at the output and delivers the output signal voltage when the control input has the same voltages as this. The same also applies to a specific input signal voltage being supplied for the other multivibrators M 4 45 provided; this output signal voltage disappears and M 5. This chain circuit from the multivibrators again, even if a certain gates M2 to MS can still be extended to the blocking input. Input signal voltage is supplied.
the. The delay times for the intended. In the circuit according to FIG. 1, the locking gate multivibrators M 2 to M 5 can be selected in a manner suitable for the purpose of using S 2 with its control input to the pulse output 50 α 1 of the multivibrator Af 1 and with its Lock-pure and do not need to be equal to each other. output to the pulse output & 1 of the multivibrator M 2

In addition to the impulses, the multivibrators are also connected. When the multivibrator Ml in its

If a 1 to e 1 are still in the following as an inverting working position, the control input receives the

Pulse outputs designated further outputs α 2 blocking gate S 2 a certain input signal span

provided to e2 . With every multivibrator there is a voltage of 55, and the blocking gate gives an output signal

the inverting pulse output in the rest position of the voltage. This is given until the

The multivibrator that hits the multivibrator comes into its working position, where-

supplies, which is the same as in the working position of the multi-through now also the blocking input of the blocking gate

vibrators occurring voltage at the associated S 2 is supplied to the specific input signal voltage

Pulse output is. In the working position, at In- 60, and therefore at its output J 2 the

vertier pulse output delivers a voltage, the output signal voltage disappears again. Select

equal to that at the pulse output in the rest position of the rend of a delimited period of time that is shorter than

Voltage occurring in the multivibrator. If you choose the period of time during which the expensive voltage is on

to determine the polarity of the voltages a multivibrator Ml is switched on, delivers the

Reference point between these two voltages 65 blocking gate S2 an output signal voltage, whose

lies, one can then also say that the pulse-voltage curve shown in curve 2 of FIG.

the output of the multivibrators provides the voltage pulses.

have the same polarity as at their input and a voltage inverter is switched on

that they at the inverting pulse output, on the other hand, the switching element that is in the rest position and in the

have reversed polarity. The voltages occurring at the outputs from the working position onwards

interchanged between the pulse output bl and the connected gate, a coincidence gate must be used instead of a blocking gate in order to obtain an output signal voltage with the same profile. In this case, in the rest position of the multivibrator M 2, one input of this coincidence gate already receives the determined input signal voltage. When the multivibrator M 1 comes into the working position, the pulse output al

Multivibrators Ml is applied, this multivibrator comes into the working position. As a result, the inverting pulse output α 2 no longer supplies any input signal voltage for the mixer gate P 14, at whose output p 14 the output signal voltage therefore also disappears. When the multivibrator M 3 comes into the working position in the course of the successive change of operating position in the individual multivibrators , its pulse output delivers c 1 as well

connected input of this coincidence gate the io of the inverting pulse output d2 of the multivibrator input signal voltage, and its output supplies the M 4 to the input of the output signal voltage connected to it. The delivery begins so coincidence gate KA the input signal voltage, at the same time as the locking gate S 2. If
then the multivibrator M 2 in the working position

Therefore, the coincidence gate KA delivers the output signal at its output from this point in time onwards.

comes, the tension via the inverter, which reaches the mixer gate P 14, disappears. This leads to the input signal voltage again, and the Koin- therefore outputs again from this point in time. The extra gate terminates the supply of the output signal voltage. This also happens in the same

Point in time as with the blocking gate S 2. This coincidence

output signal voltage from, until the multivibrator M 4 comes into its working position, after which its inverting pulse output d 2 no longer the

denzgatter thus replaces the blocking gate S 2. If the required input signal voltage for the coincidence is now 20, the multivibrators themselves are already able to supply denzgatter KA . Therefore, this Koinziihrem provides an output the same voltages ERS denzgatter the output voltage also give, as otherwise p by means of voltage inverters no longer 14 to the mixing gate P The curve are generate 14 ZiU, it may be a coincidence gate in Fig. 2 shows the Connect the course of the voltage at the Ausauch directly with its one input there. 25 gear of the mixing gate P 14.

Such outputs are now the already mentioned In- It should also be noted that the mixed inverting pulse outputs α 2 to e2. Accordingly, gate P 35 supplies is not needed and by simple coincidence gate K2, the advertising replaced to the pulse output connection of the relevant lines al and to the inverting pulse output b2 reasonable the can is when the function of the coincidence gate closed, the same output voltage as 30 is not affected by a voltage supplied to its output, the blocking gate 6 "2. and it also the effect of

The coincidence gates K 3 and K 5 are accordingly to prevent voltages acting on their output from preventing their inputs, like the coincidence gate if 2 from the pulse output. The same also applies to a multivibrator and to the inverting pulse output the mixing gate P 14 if the function of the multivibrator M 1 multivibrator is connected via the inverting input of the next following 35 pulse output a2 in the chain circuit. Which cannot be disturbed by them.

given output signal voltages are given by the In Fig. 3 is an embodiment for a part

Curves k 3 and k 5 shown in FIG. The outputs of the basic circuit shown in Fig. 1, these two coincidence gates are shown on the mixer from which one can see how the structure of this gate P 35 is summarized, which provides an output signal 40 device for generating recurring pulse voltage, as shown in the Curve p 35 in Fig. 2 groups from the available components is shown. Here one of two impulses can be requested. The standing pulse group is generated here. The coincidence gate multivibrators by symmetrical flip-flops .K "34 is formed with two transistors connected to the multivibrators M 3 and M 4, each of which is closed so that one transistor becomes conductive and one transistor times over the delay 45 operating position of the two multivibrators extending pulse is inhibited. delivers change when changing the operating position, as well as the curve k 34 in Fig. 2., both transistors their operating state. the the

Of the many possibilities of interconnection of coincidence switching tipping stage in different input of a delayed responsive transistor manner, there is an additional one in the base -Emitter path of that transistor of the combination of the coincidence gate KA and the flip-flop, which is shown in the working position of the flip-flop mixer F14. One input of the circuit is conductive. In this state, the mixing gate P 14 is due to the inverting pulse output a change in the charge of the delay path α 2 of the multivibrator M 1. The other input 55 capacitor is prevented. There are three such Kippist via the coincidence gate X "4 at the pulse stages and a coincidence response e1 of the multivibrator M 3 connected to this and to the inverting gate, which is also connected to a special amplifier pulse output d 2 of the multivibrator M 4. Further coincidence gates sen. In the idle state of the device, i.e. before the can be used in an analog manner. Input ζ of the multivibrator Ml, the control chip 60 blocking gates can be provided, voltage is switched on, the inverter already supplies the pnp -Transistors Γ11 and Γ12 with their assigned

Pulse output α 2 of the multivibrator Ml at the hearing resistors form the flip-flop M 1, one input of the mixing gate P 14, the input signal voltage to the multivibrator M 1 of the circuit according to FIG. Therefore the output also delivers the corresponding. The two directional conductors Gl and G 2 and the mixing gate P 14 the output signal voltage. The resistor Rl together form the coincidence-coincidence gate KA is initially only at its gate K2 with the inputs a1 and a2 and the one input with the input signal voltage ver output k2. A transistor is also provided at the output k2, specifically to the storage amplifier stage connected to the inverting pulse output, the input connected to the terminal d2 of the multivibrator M 2. k2 ' an output suitable for the other controls. If the control voltage supplies input signal voltage to input s of the 70. It will now be first

the structure and function of the transistor flip-flops and the coincidence gate and then their interaction, as far as it is necessary for understanding of the invention is required.

The toggle switch M 1 is controlled with the help of the changeover contact y connected to input 2 . In the rest position, the positive voltage + U is applied to the input s via the contact y . The resistor RIl is smaller than the resistor R 12. The rest of the flip-flop is constructed symmetrically. In the rest position of the flip-flop Ml , the effect of the voltage + U, the transistor T 11 is blocked and the transistor T 12 is conductive. When the changeover contact y is brought into the working position and thereby the control voltage - U is connected to the input s , the transistor T 11 is made conductive and thereby blocks the transistor T12. The toggle switch assumes its working position. When the changeover contact y returns to its rest position, the toggle switch also assumes its rest position again. To the collector of the transistor T12 of the output pulse is simultaneously al and to the collector of the transistor Til the inverting pulse output is connected α 2 of this flip-flop.

The flip-flop M 2 is constructed similarly to the flip-flop M 1. However, it also contains the delay capacitor C 2, which in this example is parallel to the base-emitter path of the transistor T 21. The flip-flop M 2 works similarly to the flip-flop Ml. In the rest position of the flip-flop M 1, the collector of the transistor T 12 is at ground potential, since this transistor is then conductive. At the center tap of the voltage divider formed from the resistors i? 29 and R27 , one end of which is connected to the collector of the transistor T 12 and the other end of which is connected to the positive voltage + U ; the base of the transistor Γ 21 of the toggle switch M 2 is connected. It therefore picks up a positive voltage in the rest position of the flip-flop Ml, and the transistor T 21 is safely blocked, while the transistor T 22 is conductive. A positive voltage that exceeds the required reverse voltage is established at the delay capacitor. When the flip-flop M1 comes into the working position, the transistor T 12 is blocked, and its collector voltage is determined by the voltage - U supplied via the resistor R 14: it is therefore much more negative. The state of charge of the delay capacitor C2 is therefore changed via the voltage divider R29 / R27 connected to the collector. The time constant determined by the capacitance of the delay capacitor C 2 and the effective resistances of the recharging circuit is decisive for this. The voltage at the base of the transistor T 21 thus follows the change in the voltage at the pulse output α 1 of the toggle switch MIj with a delay, and indeed it drops. When the base voltage has dropped sufficiently, the transistor Γ 21 is conductive, and the transistor T 22 is blocked because of the coupling of these two transistors. The voltage at the base of the transistor T21 is then practically the same as that at its emitter. This voltage keeps the transistor T 21 in the conductive state and is not undershot in the course of the voltage change on the delay capacitor. The toggle switch M 2 has thus come into its working position with a delay.

When the flip-flop M 1 comes to rest again, the ground voltage occurs again at the collector of the transistor T 12, which results in a discharge of the delay capacitor. This discharge also takes a certain period of time. However, this time the transistor T 21 changes its operating state right at the beginning of the change in the state of charge of the delay capacitor. As soon as the voltage on its base becomes more positive than on its emitter, the transistor T 21 is blocked and the flip-flop process in the flip-flop circuit M 2

ίο takes place immediately, which means that the transistor Γ 22 becomes conductive again. Since at the beginning of the process with transistor T21 the base voltage is equal to the Was emitter voltage, the base voltage becomes more positive than the emitter voltage in a very short time. Thereafter the base voltage continues to rise up to its final value.

Overall, the result is that the flip-flop M 2 when the control voltage is switched on - U comes into its working position with a delay and when switched off the-

ao ser control voltage - U returns to its rest position without delay. The pulse output δ 1 is connected to the collector of the transistor T 22 and the inverting pulse output b 2 is connected to the collector of the transistor T 21. The flip-flop M 3 corresponds completely to the flip-flop M 2 and is connected to it in the same way as the flip-flop M 2 is connected to the flip-flop Ml. The delay capacitor C 3 can have the same size as the delay capacitor C 2.

The coincidence gate K2 is connected to the outputs a1 and & 2 of the flip-flops AfI and M 2 . If the flip-flops are all in the rest position, so is the pulse output al ground voltage and the inverting pulse output b2 a negative voltage nearly equal to the voltage - U. At the output k2 of the coincidence gate K 2 , the ground voltage asserts itself via the directional conductor G 2 . The pnp transistor T connected to its base at the connection point between the resistors R2 and i? 3 receives a positive voltage and is therefore blocked. This positive voltage is established according to the voltage drop from the positive voltage + U applied to resistor R3 to the ground voltage at resistor R2 across these two resistors. If the S expensive voltage - U is applied to the input of the flip-flop M 1, this comes into the working position. The voltage - U acts via the resistor i ?14 at the pulse output a1 of the flip-flop circuit Ml and via the resistor i ?23 at the inverting pulse output 62 of the flip-flop circuit M 2. At the output k 2 of the coincidence gate K2 , the voltage - U acting there via the resistor R 1 is no longer suppressed, but occurs there as the output signal voltage of the coincidence gate K 2 . The voltage divider consisting of the resistors R2 and i? 3 is therefore fed on one side by a more negative voltage than before, so that the voltage taken from the center tap also becomes more negative and the transistor T is made conductive. A signal output voltage therefore now also appears at the output k 2 ' of the transistor amplifier stage equipped with the transistor T.

When the flip-flop M 2 comes into its working position after its response time has elapsed, ground voltage occurs at its inverting pulse output & 2 because the transistor T 21 is now in the conducting state. This asserts itself through the directional conductor G2 to the output k2 of the coincidence gate K2 , which means that the output

output signal voltage - U disappears again. The transistor T is blocked again. The coincidence gate K 2 of the circuit of FIG. 3 thus operates in exactly the same way as the coincidence gate K 2 in the circuit according to FIG. 1.

Finally, it should be pointed out that the multivibrator Ml can also oscillate freely. In this case, the pulse groups intended for sequence control would be supplied by the device in constant repetition. If they are not needed, they can then be suppressed by a special intervention in the multivibrator Ml, which ends the automatic constant change between its operating positions.

Claims (7)

PATENT CLAIMS: 1. Circuit arrangement for generating recurring pulse groups using multivibrators, in which the outputs of the multivibrators are guided via coincidence circuits delivering pulse groups at their outputs and in which the duty cycle and the frequency division ratio of the multivibrators are selected so that the pulses delivered by the first multivibrator are the desired pulse groups are hidden, according to patent application S 56779 VIII a / 21 a ³ (German Auslegeschrift 1 057661), in particular for sequence control in telecommunications systems, characterized in that the first multivibrator (Ml) is externally controlled and can be reversed without delay in both directions and that all by these controlled further multivibrators (M 2 to MS) are delayed from the rest position to the working position and can be reversed without delay from the working position to the rest position (Fig.l). 2. Circuit arrangement according to claim 1, characterized by one of the first multivibrator (Ml) controlled, composed of similar multivibrators (M 2 and M 3), in which the input of each subsequent multivibrator (M 3) with that output of the previous one Multivibrator (M 2) is connected, which emits an output pulse as a pulse output, which has the same polarity as the pulse fed to its input. 3. Circuit arrangement according to claim 2, characterized by at least one with its controlling input to the one output pulse of the same polarity as the input pulse emitting pulse output (a 1) of a multivibrator, for example the controlled multivibrator (Ml), and with its controlled input to the likewise one Output pulse of the same polarity as the pulse output emitting the input pulse (b 1) one of the following in the chain, e.g. B. the next, further multivibrator (M 2) connected coincidence circuit (.S ¹ 2). 4. Circuit arrangement according to claim 2 or 3, characterized by at least one with its one input to the one output pulse of the same polarity as the input pulse emitting pulse output (a 1 or b 1) of a multivibrator (Ml or M 2) and with its other input to the an output pulse of opposite polarity as the pulse output emitting the input pulse (& 2 or c2) one of the following in the chain, e.g. B. the next, further multivibrator (M 2 or M 3) connected coincidence circuit (K 2 or K 3). 5. Circuit arrangement according to one of claims 2 to 4, characterized by at least one the outputs (k3, kS) of coincidence circuits (K 3, K 5) decoupled from each other summarizing coincidence circuit (P 35). 6. Circuit arrangement according to one of claims 2 to 5, characterized by at least one the outputs (α 2, £ 4) of multivibrators (Ml) and coincidence circuits (if 4) decoupled from each other summarizing coincidence circuit (P 14). 7. Circuit arrangement according to one of claims 1 to 6, characterized in that the delayed in the working position reversible multivibrators (z. B. M2) each from one with a non-conductive transistor in the idle state (z. B. T 21) and one in the idle state There are symmetrical flip-flops equipped with a conductive transistor (e.g. T22), which can be switched to the working position with a delay via a capacitor (e.g. C 6) connected to the base electrode of the transistor (e.g. T 21) that is non-conductive in the rest position is (Fig. 3). Publications considered: German Patent No. 895 539. 1 sheet of drawings I 009 590/86 8.60