DE1194921B - Circuit arrangement for telecommunications systems, in particular telephone dialing systems, in which the state of charge of capacitors is changed to measure two time processes, preferably to check pulse series for pulse and pause duration - Google Patents

Description

Circuit arrangement for telecommunication systems, in particular telephone dialing systems, for measuring two time processes, preferably for testing pulse trains on pulse and pause duration; the state of charge of capacitors is changed In Telecommunication systems, especially in telephone systems, are used to check the proper function and the tolerance limits of impulse transmitter test equipment used, with which it is possible through various measurements the individual To determine work values of impulse transmitters. This happens with the known Arrangements in such a way that for separate monitoring of current surges and current breaks Zeitrneßkreise are provided with capacitors at the beginning of the test be brought into a fixed initial state and their state of charge then during of the test process is changed, which gives a measure of the duration of the Discharge power surges and power breaks.

The disadvantages of such arrangements are evident in the elevated ones Requirements z. B. be placed in self-dialing remote service. Here it comes on creating test facilities that allow direct monitoring of the pulse-pause ratio enable and exceed or fall below specified tolerance limits in to be displayed in as short a time as possible.

In the known devices of the type mentioned at the outset, there is on the other hand, only the possibility of changing the duration of pulses or pulse pauses to measure, which is a high effort due to the separate measuring circuits required on components. A direct measurement and display of the relationship between the two Time processes are not possible when using these known devices.

By means of a further known circuit arrangement, it is possible the quotient of the switch-on and switch-off time of a pulse generator directly to measure, but the effort for this arrangement is due to the separate measurement the switch-on and switch-off times by means of a counter driven by an oscillator high frequency is controlled, as well as by a special quotient measuring mechanism very high.

The object of the invention is to create an arrangement with which it is also possible to change the ratio of two time processes by changing the state of charge to measure capacitors directly and evaluate them automatically. At the same time should this reduces the cost of components compared to the known arrangements will.

This object is achieved in that the known measurement and display of the relationship between the two time processes when the two were checked Time processes in their state of charge in the same direction changed capacitors at the end of the test process are connected in series in opposite directions and that the through the series connection on the two capacitors resulting in total voltage in itself is evaluated in a known manner in a test circuit.

By using the two capacitors connected in series in opposite directions Occurring total voltage you get a measured variable that shows the relationship between the two Indicates time processes as a ratio. This proportionality of the total voltage to the The relationship between the two time processes results from the time dependency of the Capacitors as a result of the charge change prevailing voltage.

The test circuit can, depending on the requirements with regard to the measurement result from a test element (e.g. polarized relay) with a reference voltage source or consist of a voltmeter.

According to a development of the invention, for example, for the Case of measuring the pulse-pause ratio of impulse transmitters, the state of charge one of the two capacitors during the current surge series - continuously, that of the second Capacitor changed in the rhythm of the individual impulses or pauses.

As a result, the cost of components can be further reduced because with such an arrangement monitoring of the same number of power surges and power breaks due to a special counter device is not necessary is. On the other hand, this gives the possibility of a given tolerance range the charging circuits are optimal for the expiry time of the series of current impulses to be measured dimension and thus the influence of the elapsed time on the pulse-pause ratio to a minimum.

Furthermore, the independence of the measurement result from the expiry time the dial can be increased by the fact that the change in charge of the two Capacitors for measuring the ratio of two time processes through different Time constants are determined, which are set by the charging resistors in such a way that that only if the ratio to be measured deviates from a given mean nominal value results in a total voltage, the direction of which with respect to the specified Comparison voltage, exceeding or falling below the mean setpoint by one specifies the tolerance limit value.

Achieved z. B. a pulse-pause ratio to be tested the specified mean setpoint, there is no total voltage in this case, since then just have to cancel the voltages of both capacitors. Under application This condition enables the charging resistors to be dimensioned accordingly.

Another possible solution is that the time constants for the charging of the two capacitors through the charging resistors are that the test process is within the specified tolerance range of the the ratio to be measured results in a total voltage with a constant direction and that the total voltages resulting from two successive test processes with two different the two tolerance limits of the time ratio to be measured specified comparison stresses are compared.

Together with an automatic evaluation circuit, this enables Arrangement, for example, in telecommunications systems, a quick and direct check of the Pulse-pause ratio of dials.

For many practical applications, the measurement accuracy of the arrangement according to the invention are additionally increased by the two capacitors in front Beginning of the test process are charged to the operating voltage and that during the test change in charge when the operating voltage is reversed in that for pre-charging opposite direction takes place.

In this way it is achieved that the charge reversal of the two capacitors takes place in the same way as charging with double the operating voltage. In order to larger voltage changes result per unit of time with the same sensitivity the evaluation devices give a greater accuracy of the measurement result.

With reference to FIG. 1 to 5 are the structure and mode of operation below two embodiments according to the invention described in detail.

The in F i g. 1 enables the direct measurement of the pulse-pause ratio of. Number switches compared to a given average setpoint. In the idle state in this circuit arrangement, the capacitors Cl and C2 are charged to the operating voltage via 1st earth, 3v 2, 1v 1, Cl, 2v 3, R3, R4, -or.

2. Earth, 21, 2, 2 v 1, i, C2, 2 v 3, R3, R4. -A relay I (not shown) is actuated by the series of impulses to be tested for its pulse-pause ratio, so that the series of pulses is transmitted through contact i to the test circuit according to FIG. 1 transmits. With the first pulse of a series of impulses, a not shown drop-out delayed relay V1 is actuated. After the end of the first pulse, drop-out delayed relays V2 and V3, which are also not shown, respond in the order of their code numbers and remain attracted during the entire series of current impulses. Contacts 1v 1, 2v 1 to 31, 2 are assigned to these relays, which switch the charging circuits for the capacitors C1 and C2 at the beginning of the series of impulses. When the contact 1, v 3 is switched, the capacitor Cl is continuously charged up to the end of the series of pulses in the opposite direction to the precharge via 3rd earth, 3 v 1, Cl, 1 v 1, 1 v 3, R l, -.

After the contact 1v 2 is closed, the capacitor C2 is charged in pulses and also in the opposite direction to the precharge via 4th earth, 3 v 1, C2, i, 1 v 2, R 2, -. By reversing the polarity of the two capacitors C1 and C2 at the beginning of the test process and the resulting charge reversal, the voltage across the capacitors C1 and C2 reaches a value at the end of the test process which is greater than the operating voltage Ub. At the end of the series of current impulses to be tested, relays V1, V2 and V3 drop out again in the order of their code numbers. The contacts assigned to them return to the rest position. The following test circuit is closed during the period of time caused by the drop-out delay of relay V2, in which the contacts of relay V1 are already in the rest position, but those of relay V2 are still in the working position: 5.P (1), 2v 2, 2v 1, i, C2, Cl, 1v 1, 3v 2, B, The comparison voltage is set at the two voltage dividers. It becomes effective when contact 2v 3 is in the working position, via 6th earth, 2v 3, R3, R4, -.

Due to the series connection of the capacitors Cl and C2 in opposite directions Polarity comes in the test circuit 5 as the sum voltage, the difference between the two capacitor voltages to the effect. The direction of this total voltage is determined by the size of the two capacitor voltages to each other. Via the diode D1 or D2 this now results if the total voltage deviates from the comparison voltage set at R4 or R3 an equalizing current through the polarized test relay P, which in itself better known Way controls a display device not shown.

For a more detailed explanation of the processes described are used in FIG. 2 shown basic charging curves for the capacitors C1 and C2. In the case of testing the pulse-pause ratio of number switches, the curve U2 = f (ti) shows the dependence of the voltage on capacitor C2 on the total time of a certain number of pulses. The curve U1 = f (ta) shows the dependence of the voltage on the capacitor C1 on the expiry time ta of the dial associated with this specific number of pulses. For the voltage U2, three curves are shown which correspond to different pulse-pause ratios vu, vm, vo. By specifying a minimum and maximum expiry time (tal; tat) and a minimum and maximum pulse-pause ratio (vu, v "), the contemporary working range for the curves is defined. The definition of the time constants T1 and T2 for charging the capacitors C1 and C2 takes place on the assumption that the measurement is as independent as possible from the elapsed time ta. The charging of the capacitor C2 is determined by an average time constant, which is given by an average pulse-pause ratio vm.

The relationship between the two curves U1 and U2 is briefly explained below. The total voltage of the two capacitors Cl and C2 that affects the test circuit 5 is: With the introduction of the pulse-pause ratio surrendered The requirement for complete independence of the measurement result and thus the total voltage Us = U2- U1 from the elapsed time ta can only be met if the two exponents in the above formula (b) are the same. From this it follows as a condition for the two time constants T1 and T2: As shown in FIG. 2, this condition can only be fulfilled for a certain pulse-pause ratio, in the present case for the mean ratio v. But since the mean charging curve U2 (vm = c "nst) = f (ti) does not run parallel to the two limit curves U2 (vu = c" nst) = f (ti) and U2 (v " - tonst) = f (ti) , when changing the elapsed time ta and the associated voltage change across the capacitor Cl along the curve U1 = f (ta), different total voltages Us result with the same pulse-pause ratio as soon as this deviates from the specified mean value v.

The resulting influence of the elapsed time on the measurement result can be kept low by dimensioning the time constant T2 accordingly. The starting point for this is the fact that for two exponential functions there is one gives a common abscissa value for which they have their greatest distance from one another, so that for every pair of exponential functions there are also two abscissa points, for which the distances between the two curves of a curve pair are the same. The bulging of the one curve with respect to the other is subject to the existing measurement inaccuracy accepted.

On the in F i g. 2 charging curve shown for an average pulse-pause ratio v. the work area is determined by the points P and Q according to the expiry time limits tal and tat. The pulse times ti (,.) And ti2 (z, m) correspond to them. For the limit curves U2 (vu - tonst = f (ti) the time limits of the working range are at til ("u) and ti2 (vu). The sum voltages Usl (vu) and Us2 (, u) occur at these limits For the limit curve U2 (vo = "onst) = f (ti), the time limits of the working range are at til (") and ti2 ("). The sum voltages Usl (,") occur at these limits. and Us2 (vo). According to the above consideration, the distances between the curves at the boundaries of the respective working area must be the same: Usl (, u) = US2 (vu), Usl (") = Us2 (v"). (d) These two condition equations result two time constants for the charging curve U2 (vm = conss) = f (ti), from which an average value is to be calculated, since the charging process of the capacitor C2 can only be determined by a time constant value and around the resulting error for the two limit curves as far as possible to be kept low. About the relationship (c) the time constant T1 for the charging curve U1 = f (ta) can then also be calculated. In an arrangement according to FIG. 2 is dimensioned according to an average pulse-pause ratio vm, when testing results in a total voltage across the two capacitors C1 and C2, if the pulse-pause ratio to be measured changes from the value v. deviates. For this purpose, the measuring process for a number switch with the expiry time tal and the pulse-pause ratio vu is explained as an example. During the testing process, the capacitor Cl charges up to the voltage UI during the expiry time tal. However, the voltage across the capacitor C2 only reaches the value U2, since the pulse-pause ratio deviates from the value vm. This results in a total voltage Us. When their direction is evaluated by the test relay P, the pulse-pause ratio vu results directly from their size. The relationship can be seen from FIG. 2 easily deduce.

F i g. 3 shows another circuit arrangement in which the charging resistors R1 and R2 and thus the time constants T1 and T2 are dimensioned so that a course of the two charging curves for the voltages U1 and U2 results, as shown in F i g. 5 is shown in principle.

F i g. 4 shows a circuit arrangement according to FIG. 3 belonging Display device that contains two additional windings of the test relay P. To with the circuit arrangement according to FIG. 3 a pulse-pause ratio for compliance Checking the upper and lower tolerance limits is a double check a certain pulse series required. The function of this circuit arrangement according to FIG. 3 is briefly described below as far as it differs from Arrangement according to FIG. 1 concerns. After precharging the capacitors C1 and C2 at the beginning of the pulse series to be tested, the capacitor Cl during the entire Expiry time charged. The capacitor C2 is charged in pulses via the contact i. Following the pulse train, capacitors C1 and C2 are reversed Polarity connected in series, so that a total voltage is formed on them.

One is connected to R3 via the voltage divider R3 and a contact 4e set reference voltage on capacitor C3, the z. B, the lower given Tolerance limit. This is used for the period of charge equalization and testing in the test circuit as a power source with low internal resistance. As shown in FIG. 5, the time constants TI and T2 are through the resistors R 1 and R2 dimensioned so that the total voltage of the two capacitors Cl and C2 always has the same direction. The sum voltage arises in the test circuit and the comparison voltage set at R3 is a voltage difference that depends on The size of the total voltage can have changing direction.

Depending on the direction of this differential voltage, there is a current flow in alternating direction through the polarized test relay P. If the pulse-pause ratio to be tested is above the lower tolerance limit specified by the voltage divider R3, the contact p of the test relay P in the evaluation circuit according to F i G. 4 brought into its character position z. The relay E picks up on 7th earth, 3 v 1, p, 2 e, E, -. Due to the contact 1 e, the relay E is held during the following test process. With the contact 4e in the circuit arrangement according to FIG. 3 the comparison voltage set at the voltage divider R4 fthe upper tolerance limit of the pulse-pause ratio to be measured is switched into the test circuit. If the value of the total voltage remains below the comparison voltage set on the voltage divider R4, the pulse-pause ratio to be measured is below the upper tolerance limit. The test relay P switches its contact p to the separating layer T. In the evaluation circuit according to FIG. 4 pulls the delayed relay F on via B. Earth, 3v 1, p, T, G, 3e, F, -. The test process is ended by the relay F. The in F i g. 5 shown charging curves for the capacitors C1 and C2 differ from those in FIG. 2 charging curves shown only by an increase in the pulse-pause ratio v. applicable charging curve. This increase ensures that the respective total voltage Us always has the same direction. In the upper part of FIG. 5 shows a voltage diagram that shows the position of the two total voltages resulting from the measurement in comparison to the lower comparison voltage Uv 1 and the upper comparison voltage Uv2. From the charging curves according to FIG. 5, the sum voltage Usl results for an elapsed time tal and a pulse-pause ratio vu. The capacitor C1 charges up to the voltage U1 according to the curve for the elapsed time, the capacitor C2 reaches the voltage U2 according to the curve valid for the pulse time ti. This results in the total voltage Usl. For a pulse-pause ratio v, the sum voltage Us2 would result, for example. The proportionality of the respective total voltage to the pulse-pause ratio to be measured can also be easily deduced from the drawing.

To determine the time constants, those in the description apply from F i g. 2 in an analogous manner.

Claims (7)

Claims: 1. Circuit arrangement for telecommunications systems, in particular Telephone systems for measuring two time processes, preferably for Testing of pulse series for pulse and pause duration, the state of charge of capacitors is changed for the duration of the respective time process by charging or discharging and the capacitors at the end of the respective time process with a test switching element, z. B. a polarized relay, and a reference voltage source connected in series are, d u r c h e k e n n -z e i c h n e t, that for the known measurement and display of the relationship between the two time processes when the two were checked Time processes in their charge state in the same direction changed capacitors (Cl and C2) are connected in series in opposite directions at the end of the test process and that the total voltage resulting from the series connection on the two capacitors is evaluated in a manner known per se in a test circuit. 2. Circuit arrangement according to claim 1, characterized in that the test circuit consists of a test switching element (P) and a reference voltage source (R3, R4), both with the two Capacitors (C1 and C2) can be connected in series. 3. Circuit arrangement according to claim 1, characterized in that the test circuit consists of a voltmeter, which can be connected in series with the two capacitors (Cl and C2). 4. Circuit arrangement according to one of claims 1 to 3 for measuring the pulse-pause ratio of series of current impulses, characterized in that the state of charge of one (z. B. Cl) of the two capacitors is only changed during the pulses, that of the second capacitor (C2) is only changed during the pauses in current. 5. Circuit arrangement according to a of claims 1 to 3 for measuring the pulse-pause ratio of series of current impulses, characterized in that the state of charge of one (z. B. Cl) of the two capacitors continuously during the series of impulses, that of the second capacitor (C2) in rhythm of the individual impulses or pauses is changed. 6. Circuit arrangement according to one of claims 1 to 5, characterized in that the change in charge of the two capacitors (Cl and C2) for measuring the ratio of two time processes is determined by different time constants (T1 and T2), which are determined by charging resistors (R 1 and R2) are set in such a way that only if the ratio to be measured (v) deviates from a given mean nominal value (v.), A total voltage (Us) results, the direction of which is exceeded or undershot in relation to the given comparison voltage (Uv) of the mean setpoint by a value specified by the tolerance limits. 7. Circuit arrangement according to one of claims 1 to 5, characterized in that the time constants (T1 and T2) for charging the two capacitors (Cl and C2) through the charging resistors (R1 and R2) are dimensioned so that during the testing process within of the specified tolerance range (v, and vu) of the ratio to be measured results in a total voltage (Us) with a constant direction, and that the total voltages (Usl and Us2) resulting from two successive test processes with two different, the two tolerance limits of the time ratio to be measured Comparison voltages (Uvl and Uv2) are compared. B. Circuit arrangement according to one of claims 1 to 7, characterized in that the two capacitors (C1 and C2) are charged to the operating voltage (Ub) before the start of the testing process and that the change in charge which occurs during testing when the operating voltage (Ub) is reversed in the in the opposite direction to precharge. Documents considered: German Patent No. 969 576; German interpretative document No. 1 141 683.