DE1138119B - Circuit arrangement for the true-to-time transformation of irregularly deformed direct current pulses generated by current impulse transmitters in telecommunications, in particular telephone switching systems, into simultaneous square-wave voltage pulses or contact actuations - Google Patents

Description

Circuit arrangement for true-to-time reshaping of irregularly deformed, generated by surge transmitters in telecommunications, in particular telephone switching systems Direct current pulses into simultaneous square-wave voltage pulses or contact actuations The invention relates to a circuit arrangement for true-to-time forming of irregularly deformed direct current impulses, which are emitted by current impulse transmitters (e.g. from a number switch contact which interrupts a quiescent current in pulses nsi) generated in telecommunications, in particular telephone exchanges and at any Set the lines leading them with regard to their duration or for distortions their duration are to be measured in simultaneous square-wave voltage pulses controlling a pulse timer or contact actuations using one of the rising and falling edges the amplifier differentiating in terms of their duration impulses to be measured, the a bistable multivibrator is connected downstream, which in turn has an output or Contact controls which leads to the pulse timer.

To measure the switching times of impulse transmitters, e.g. B. of number switches Typically, writing pulse timers are used in telecommunications systems. Used you can do this without activating the number switch for spark extinction Measurement errors from ± 1 ms to ± 4 ms. But if the measurement, as often desired, over If a longer line is made, the measurement errors are even greater. The use of the impulses and also the impulse duration can then be determined exactly if one for the measurement uses a loop oscilloscope. Apart from being trained for this Forces have to be used, this effort is usually too great. Also for measurement the pulse duration distortion in the transmission equipment of a telephone exchange, z. B. in an exchange transmission of a private branch exchange, a loop oscilloscope must usually be used can be used because the pulse generating contact is only used once is available. One can therefore generate unusable impulses and they simultaneously to a writing pulse timer.

The German patent specification 918151 already provides a circuit arrangement for real-time amplification of direct current pulses, the inductive of an amplifier circuit and then fed to a polarized relay, especially for testing Number switches in telephone stations known in which the polarized relay for the purpose Recording of shape-distorted direct current pulses before the beginning and end of each pulse is increased in its sensitivity.

In this known circuit arrangement, however, the existing line must be separated at the desired point, which is always an undesirable one Intervention means. Since this known circuit arrangement with its low resistance If the input is in series with the actual working or useful circuit, it can influence the intended effect there in addition in an undesirable manner. In order to avoid these disadvantages, it is already known to use pulse timers in telephone systems to be connected to the line in parallel with high resistance and potential-free at any point on the line.

Furthermore, the German patent application 1007 810 describes a circuit arrangement for equalization of a supplied by a photo resistor and then amplified Photocurrent known, depending on the steep change in the photocurrent At the beginning of a light control pulse, a discharge vessel is ignited and dependent from the steep change in the photocurrent at the end of the light control pulse. by switching means controlled by it is again punched in order of itself to be a rectangular one Build up impulse, the beginning and end of which correspond to the light control impulse.

In this known circuit arrangement is the rise and Falling edges of the light control pulses differentiating amplifier a bistable Toggle circuit connected downstream, which in turn has a Output controls. But even with this known circuit arrangement, the special task of Reshaping of irregularly deformed direct current impulses to be measured with regard to their duration cannot be solved because in addition to the only interesting rising and falling edges at the beginning and end of the pulses in a disruptive manner during the pulses in their voltage curve additional steep spots can occur, e.g. B. by transmission distortion. The invention solves this problem in that the converter is known per se Can be connected in parallel to the desired line points with high resistance and potential-free is that the differentiating amplifier for the rising and falling edges of the Impulses each have a separate channel and through possibly multiple differential ion, Limitation by means of pre-stressed thresholds and amplification only of the increase or decrease Falling edge generates corresponding input pulses for the bistable multivibrator, so that their one position is always the current-filled pause between two pulses and whose other position is always assigned to the pulse duration, and that between the time-wise The rising and falling edges to be determined also disruptively in the voltage curve of the impulses to be reshaped are ineffective.

Another embodiment of the invention, in which the bistable of the Toggle controlled output for the downstream, possibly writing Pulse meter is designed as a relay circuit, is that a first polarized relay with its two excitation windings in opposite directions in one each of the two anode leads is looped in such that its contact during the duration of each pulse a control winding one with its other winding in a local circuit continuously excited in opposite directions, second polarized relay switches on so that its contact leads to the closed circuit leading to the pulse timer opens exactly for the duration of the impulses to be measured.

The converter according to the invention is explained using an exemplary embodiment shown in FIG. The converter is connected in a manner known per se with high resistance and potential-free with its input terminals a (-) and b (-) in parallel to any point L 1, L 2 of the line at which the pulse duration is to be measured. To measure the duration of the pulses from a number switch contact nsi or the pulse duration distortion of a transmission device, the connection is made, for example, as shown in Fig. 2 or Fig. 3.

The voltages U, U 1, U 2 at the input terminals a (-), b (-I-) of the converter have roughly the curve shown in Fig. 4. At the input, the primary winding of a transformer Ue is in series with an ohmic resistance W of about 20 kOhm. The current in the input is essentially determined by the ohmic resistance W and therefore has approximately the same curve shape as the voltage effective at the input. The transformer Ue converts this current in a known manner into a secondary voltage proportional to its differential quotient. In the opening and closing times of a number switch contact nsi, this secondary voltage always has a very steep leading edge. These two leading edges represent the start and end times of the pulses to be measured with great accuracy. The voltage peak for the start or opening time has a different polarity, steepness and amplitude than the voltage peak at the closing time. The invention is based on this fact, which is known per se.

Due to the different polarity, the two voltage peaks can easily be separated from one another and brought into the form required for controlling a bistable multivibrator. Such a bistable multivibrator is shown, for example, in Fig. 1 in the form of two tubes Rö 5 a and Rö 5 b . Various transistor circuits are also known for this purpose and can be used accordingly. A single amplification is sufficient for the voltage peaks in the closing times, e.g. B. in Fig. 1 through the tube Rö 4. Since the grid of this tube is sufficiently negatively biased, only those positive voltage peaks p are effective, the size of which exceeds a certain value. They cause anode current pulses that cause voltage or input pulses sch at an anode resistor W 4, with which the tube Rö 5 b is controlled.

To obtain the input pulses ö for the <opening times, the voltage induced in the secondary winding is first freed from all positive (p, po) and small negative (ne) amplitudes by a diode Rö 1 (see Fig. 4), so that only the voltage peaks (n) can reach the grid of the tube Ro2 at the time of opening even with a relatively large negative amplitude. You can also let this tube Rö2 work in the upper bend of the characteristic curve, so that only the negative voltage peaks are amplified. At the anode resistance of the tube Rö 2, positive voltage peaks arise, which are differentiated again on the series connection of capacitor C and resistor W 5. The resulting voltage peaks sp are fed to the control grid of the tube Rö 3. This tube works in exactly the same way as the tube Rö 4, so that only the positive voltage peaks sp arising from the second differential ion are amplified. The negative input pulses ö produced at the anode resistor W 3 of this tube are sufficient to control the tube Rö 5 a .

The circuit specified by E ccles and Jordan is shown in Fig. 1 as a bistable multivibrator. Two oppositely polarized windings of a polarized relay J are located in the anode leads of tubes Rö 5 a and Rö 5 b. Only one of these two tubes carries current. Therefore only one of the two windings is excited. When the tube Rö 5 b conducts current, the polarized relay J transfers its contact i to the separating side T , as can be seen from FIGS. 1 and 4. If, on the other hand, the tube Rö 5 a carries current, the relay J transfers its contact i- to the unused character side Z. The turnaround time - or more precisely the flight time f - of such a relay contact is about 2 ms. This flight time f lacks the duration of the contact closure both on the separating side T and on the unused drawing side Z. The contact i is therefore closed on the separating side T by this flight time f shorter than it corresponds to the pause P between the duration D of the pulse ( Df ), and the separating side contact is thus open longer than the pause P between two pulses by the flight time f (Pf). Since the downstream pulse timer usually requires a single contact that is open exactly for the duration of each pulse to be measured, the influence of this flight time f must still be switched off.

This is achieved according to a further development of the invention in that a first polarized relay J with its two excitation windings is looped in opposite directions in each of the two anode leads so that its contact i, T a control winding one with its other winding during the duration D of each pulse in a local circuit (via 2R) turns on permanently oppositely excited second polarized relay H, so that its contact h, T, opens the closed circuit leading to the pulse meter exactly for the duration of the pulse to be measured.

So if you control a second polarized relay H with the same flight time f as the relay J via the contact i, namely via its separating side T , which is closed with each pulse, the second winding, which is pre-excited in opposite directions in a local circuit via a resistor 2R, has the same flight time f as the relay J Isolating current excitation receives, this is excited via the isolating side of the contact i during the pulse duration shortened by the flight time f of the contact i with character current. As can be seen from Fig. 4, the opening time D of the separating side T of the contact h is then equal to the sum of its actuation time on the drawing side and its flight time f, which is equal to that of the contact i . This opening time D is therefore exactly equal to the duration D of the pulse, which - apart from the distortion of its duration suffered and to be determined, for example on the line or in the transmission device - is the opening time of the number switch nsi - or the contacts s I, s III of the Fig. 3 - corresponds to.

In Fig. 4, D denotes the pulse duration, P the interpulse period, ai the start-up time of relay J, ah the start-up time of relay H, which is the same as relay J - i.e. ai = ah -, f the flight time of the relay contact, that is the time , in which the moving contact swings from one fixed contact to the other fixed contact. ö denotes the point in time of the reinforced (left) pulse edge when the hsi contact opens, and Sch denotes the point in time of the reinforced (right) pulse edge when the nsi contact closes (Fig. 1).

In the upper representation of Fig. 4 under D is the example Occurring voltage curve of such an amplitude distorted pulse and below it the first derivative dU / dt with the steep right flank, the closing pulse p (see Fig.1, Rö 4).

When opening the circuit of the number switch contact is nsi by the input pulse ö tube Ro 5 a locked (see. Fig.1), so that the tube Ro 5 b thereby becomes conductive and the winding II of the relay J turns on, the. After the Start-up time ai and the flight time f the separating side T of its contact i closes. As a result, after the start-up time ah of relay H, its contact h is controlled from T to Z.

Claims (4)

PATENT CLAIMS: 1 .. Circuit arrangement for true-to-time reshaping of irregularly deformed direct current pulses; generated by current impulse transmitters (e.g. a number switch contact nsi, which interrupts a quiescent current in pulses) in telecommunications, in particular telephone exchanges, and are to be measured at any point on the lines leading them with regard to their duration or for distortions of their duration, in simultaneous square-wave voltage pulses that control a pulse timer or contact actuations using an amplifier differentiating the rising and falling edges of the pulses to be measured with regard to their duration, which is followed by a bistable multivibrator, which in turn controls an output or contact which leads to the pulse timer, characterized in that the converter (Fig . 1) in a manner known per se, high-resistance and potential-free, can be connected in parallel to the desired line points (L, L 1 or L2), so that the differentiating amplifier (W, Ue, Rö 2 to Rö 4) for the rising and falling edges the pulses each have a separate channel u nd by possibly multiple differentiation (W, Ue; C, W5), limitation by means of biased thresholds (Rö 1 or Rö 4) and amplification only the rising or falling edge corresponding input pulses (ö, sch) for the bistable trigger circuit (Rö 5 a, Rö 5 b) generated so that whose one position (Rö 5 a ignited) is always assigned to the current-filled pause P between two pulses and the other position (Rö 5 b ignited) is always assigned to the pulse duration (D), and that between the rising and falling edges to be determined over time, additionally in the Voltage curve of the pulses to be reshaped, the steep points that occur remain ineffective. 2. Circuit arrangement according to Claim 1, characterized in that an input side for the first differentiation with a high-ohmic resistor (W) in series-connected transformers (Ue) are provided is, which has a separate secondary winding for each of the two channels. 3. Circuit arrangement according to claim 2, characterized in that to limit or to suppress all steep points additionally occurring in the voltage curve of the pulses, which in the voltage derived by the first differentiation further voltage peaks with smaller positive (po) or negative (ne) Cause amplitude, in each of the two channels a sufficiently dimensioned bias voltage (-E- 2 or -5 V) is connected via the relevant secondary winding to the control electrode of the relevant rectifying threshold, which in the (upper) channel for the (negative) rising edge as a diode (Rö 1) connected upstream of the again differentiating (C, W5) channel amplifier (Rö 2, Rö 3) or in the (lower) channel for the (positive) stronger trailing edge is designed directly as a simple amplifier. 4. Circuit arrangement according to claim 1, in which the output controlled by the bistable multivibrator (Rö 5 a, Rö 5 b) for the downstream, possibly writing pulse timer is designed as a relay circuit, characterized in that a first polarized relay (J) with its two excitation windings is looped in opposite directions into one of the two anode supply lines so that its contact (i; T) during the duration (D) of each pulse is a control winding of a second polarized relay that is continuously excited in opposite directions with its other winding in a local circuit (via 2R) (H) switches on, so that its contact (h, T) opens the closed circuit leading to the pulse timer exactly for the duration of the pulses to be measured. Documents considered: German Patent No. 918 151; German Auslegeschrift No. 1007 810; Bell Laboratories Record, 1952, November, pp. 440 to 443.