DE2832643A1 - Circuit measuring telephone line capacitance - periodically switches line between voltage source and detection circuit receiving discharge voltage - Google Patents

Abstract

The capacitance-measuring circuit determines whether a telephone line or similar is functional by periodically switching between a constant voltage source and a discharge circuit at a constant frequency. The voltage appearing in the discharge circuit is passed via a filter to an evaluator that determines line capacitance. The point in time at which measurement occurs is chosen so that it is synchronized with the change-over frequency and is also determined by the edge of the voltage profile resulting when switching back to the voltage source. Measurements are almost independent of ripple.

Description

Circuit arrangement for checking capacitance values,

in particular of line capacitance values to determine the operability of the lines in telecommunications and telephone systems.

To check a subscriber line, it is known to the Charging current of the existing in the subscriber set and in series with the AC alarm clock to use lying capacitor. This method can reduce the line capacity have a falsifying effect. This is especially the case when the line capacitance is of the order of magnitude of the capacitance to be measured of said capacitor.

In a further known arrangement for checking the State of a subscriber line is the sum of the capacities of the line and the alarm clock capacitor in the subscriber set for the assessment based on. The total capacitance to be measured is provided by a constant current source charged and via a corresponding control element with a constant current unload. The line to be tested via a capacitance measurement is periodic between the charging constant current source and the discharge circuit switched. It is assumed that the connected capacity is completely charged or

is practically discharged while the discharge circuit is switched on. The charging amount of the total capacity to be assessed is determined by a in the charging circuit or a measuring instrument arranged in the discharge circuit, which can be calibrated in capacitance values is displayed.

Such a measuring instrument must be heavily damped so that the periodic switching in the display can no longer have an effect. The resulting Measurement time can have a disruptive effect if the measures to be carried out on the individual lines Measurements are to be made in quick succession, such as this, for example is the case when checking by an appropriate measuring machine.

For measuring machines of this type that constantly carry out routine checks on the Make subscriber lines, this must be used to evaluate the measurement result are available in an automatically evaluable form. The ones in the unloading or loading circuit Removable voltage proportional to the capacitance value must therefore be converted into a form which, despite their residual ripple, will be evaluated accordingly allows. With sufficient smoothing of the voltage to be assessed is for each measurement to be carried out a certain time until reaching the steady-state To take into account the measurement condition.

This can then turn out to be a required rapid measurement sequence have a disruptive effect.

The invention now also relates to a circuit arrangement for checking capacity values, in particular the capacity values of the subscriber line cables in telecommunication systems, in particular telephone systems, to determine their operability with a central, self-checking facility by evaluating the depending on the reference point on which the test is based and present in one Discharge circuit as a voltage value convertible capacitance value, the respective capacitance to be tested periodically between a constant voltage value Voltage source and the discharge circuit is switched at a constant frequency.

It is the object of the invention in terms of a routine Series check of lines the influence of the form of the measuring voltage to be evaluated to reduce the measuring time.

This is achieved in that the setting in the discharge circuit Voltage value via an integrating filter arrangement of the evaluation device as Measured value is supplied and that the time of its evaluation is chosen so that it is based on the corresponding to the switching frequency and the filter dimensioning resulting residual ripple of this measuring voltage in one and the same area is within each period and in each case synchronous to the switching frequency.

The respective times for a measurement are therefore according to the invention placed so that it is evaluated periodically with a frequency that corresponds to the switching frequency matches.

With a given fixed phase relationship, this allows the voltage generated at the output of the filter arrangement largely independent of evaluate their residual ripple. Since for the individual measurements the estimated genes State of the filter arrangement must be achieved, the measuring time of the existing Settling time of the filter depends. The settling time, in turn, depends on the permissible Determines the residual ripple of the voltage to be evaluated. In the definition according to the invention the respective measurement times have a relatively large residual ripple no longer disturbing, so that a filter arrangement with a very short settling time can be used. This also results in a minimum measuring time for the individual measurements to be carried out.

The measurement time within each period of the measurement voltage to be evaluated can be set so that it is in the immediate area of that flank after half the period starting from the Switching to the discharge circuit when switching back to the DC voltage source arises. The value to be determined for each reading time within a measurement is thus largely independent of the size of the in the filter arrangement existing capacitor for smoothing purposes. Is related to each switching period selected a point in time for the respective measurement of the voltage value at which the Capacity to be measured after charging has been carried out on the charging voltage source is switched on, this capacitance value cannot interfere with the measurement impact. Such a disturbance could occur if the capacitance to be measured of the line is in the order of magnitude of the gauging condenser used. Since the capacitance to be measured is currently switched off in relation to the measuring point, such an influence is excluded.

To make an automatic measurement for a large number of subscriber lines To be able to do this in a tight time sequence, the one at the filter output becomes the before- times seen registerable voltage value over a Analog-to-digital converter supplied to a device, the output signals processed and which initiates the subsequent functions to be linked to the measurement result.

The invention is explained below with reference to the figures.

In Figure 1 is a modified block diagram of the test arrangement shown.

FIG. 2 shows diagrams of those occurring at individual circuit points Voltage curves.

It is assumed for the arrangement shown in FIG. 1 that that an automatic check of a large number of lines should take place. the Individual measurement results are processed by the device DVA and by it the subsequent functions to be linked to the assessment of these measurement results are initiated. This facility also establishes the start time for each check to be carried out signals.

The value of the capacitance Cl constituting the device under test is among others thereof depends on whether the two voice wires a and b of a line are against each other or each individually measured against earth. When testing a subscriber line this capacitance Cl can also be the sum of the line capacitance and the capacitance of the alarm capacitor present in the subscriber set.

With the start signal that the evaluating device outputs DVA, a naktgererator, which supplies a Rechbeck voltage of 10 Hz, for example, is effective switched.

Its output is used to match the clock pulses.

a transistor T controlled via the resistor R4. There- by the relay U arranged in its collector circuit becomes in the rhythm of the clock pulses actuated. The transistor T is turned on by the diode D lying parallel to the relay the cut-off voltage of the relay U protected.

The line capacitance Cl is periodic via the contact u of this relay U charged and discharged again. The charging process takes place in the NA position Changeover switch u through the constant voltage source Q via the charging resistor R1. The connection points marked with a and b for the connection to the one to be measured Capacitance Cl should symbolically connect the measuring device to the speech wires a and b of a subscriber line.

In the NE position of the switch u, the capacitance C1 is over the Discharge resistor R2. Provided that during the respective closing times of the switch u the charging or discharging of the capacitance C1 in each case practically is completely ended, there is between the current flowing during discharge 1 and there is a linear relationship with the value of the capacitance C1 to be measured. On a display instrument that one switches to the discharge circuit and that of the periodic actuation the changeover switch u shows the mean value of the discharge current that is set, could thus directly the respective capacitance value with a corresponding calibration can be read. Such an evaluation is, however, for routine checks, in which a large number of lines in terms of their capacitance value in quick succession are to be assessed, not possible.

In the exemplary embodiment, the evaluation voltage that is used in the periodic Discharge of the capacity Cl at the counter stood R2 is created by a Filter arrangement, which in the simplified representation from the resistor R3 and the capacitor C2 should exist, smoothed. The one at the output of this filter arrangement The voltage value that arises during the measurement to be carried out, i.e. the value the capacitance Cl is proportional, is via an analog-digital converter with appropriate Coding supplied as a digital signal to the evaluation device DVA. One assumes from the fact that the respective measured value is only in the steady state of the filter arrangement is to be assessed, the settling time of this filter arrangement goes into the measuring time. The settling time in turn depends on the residual ripple, which is permissible at the output of the filter arrangement. With decreasing residual ripple the settling time increases. By choosing the right time for the evaluation of the voltage value arising at the output of the filter arrangement can be largely independent of the for the determination of this measured value existing ripple of this output voltage can be achieved. Through the analog-to-digital converter the voltage value at the output of the filter arrangement is only at those times rated, which is defined by a corresponding trigger pulse at its input TE will. These trigger pulses are now, for example, according to line E of the figure 2 placed so that they coincide with the point in time at which the switch u in each case connects the capacitance to be measured to the charging voltage Q. you The beginning therefore coincides in time with the rising edge of each of the Clock generator TG matched the pulse of the controlling pulse train. Through this it is achieved that the voltage value to be evaluated is independent in a large range has only a very short settling time of the capacitance value for C2. Through this the measuring time to be applied for each test of a line is ching decreased.

The trigger pulses with a width of about 1 ms are from the monostable Tilt stage Z1 delivered. This flip-flop is via the input El by the clock generator generated pulses are controlled with each rising edge.

This does not take place directly with the evaluation device DVA released this clock generator, but only after one on the Settling time coordinated delay time. This is done in the exemplary embodiment time stage Z2 is reached. This time stage is set by the start signal of the evaluation device started in the same way as the clock generator and it gives according to the predetermined Delay time via input E2, triggering stage Z1 free. With that immediately then applied to the input El pulse of the clock pulse sequence is then, as well as with the further pulses, with each rising edge a trigger pulse for the analog-digital converter generated. This trigger pulse then determines the point in time at which the voltage is evaluated at the output of the filter arrangement.

In FIG. 2, lines A to G are those voltage profiles shown at the points provided with the same reference numerals of the embodiment occur according to Figure 1.

Through the evaluation unit DVA is automatic for the individual routine tests carried out on the basis of a corresponding program contained in it a start signal is given in each case according to line A. This also creates the Zeitstfe /.2 started, which after the time Tv according to line B an output signal gives away. Line C shows a unit that differs from lines A and B. for the time axis of the clock generator TG delivered cycle shown. With a clock frequency of 10 Hz, for example, the period Tp corresponds to one Time of 100ms. After the start signal, the one controlled by these clock pulses remains Changeover switch u 50ms in each switch position. This is the requirement for a complete charge or discharge of the line capacitance Cl in each case Fulfills.

In line D are those at each rising edge of the individual clock pulses derived trigger pulses shown.

Line E shows the voltage curve at the line-side connection point of the toggle switch and in line F which corresponds to the periodic switchover The voltage curve that sets the resistor R2 is shown. It will be like this assumed that during each pause time of the pulse train shown in line C the changeover switch is to assume the NE position. During this time, the line capacity will be Discharge Cl. After switching the switch u to the NA position, during the capacity Cl is charged in each case after the standing time of 50 ms. The pulsed voltage at circuit point F is smoothed by the filter arrangement. At the output of the filter arrangement The curve shown in line G then results in the steady state the voltage to be assessed. With the same value for the capacitance Cl, the curve shows Fa the course with a very large value for the smoothing capacitor C2 and the Curve Fb shows the course for a value for, for example, a factor of 10 smaller the smoothing capacitor C2. It can be seen from these curves that the value of the Smoothing capacitor does not affect the measured value only if the point in time of the respective measurement based on a period with the point of intersection of the two Curves match. After half the period, this is always given when the switch is in the position NE turns over and thus the Discharge of the line capacitance begins. With the appropriate choice of the respective At the time of lease, a smoothing capacitor with a small capacitance value can thus be used will. This results in a short settling time, which means that it is accelerated Evaluation is achieved.

5 claims 2 figures

Claims (5)

Claims 1 ,! Circuit arrangement for checking capacitance values, in particular of the capacitance values of the subscriber lines in telecommunications, in particular telephone systems to determine their operability with a central self-testing facility by evaluating the dependent on the reference point on which the test is based and in a discharge circuit as a voltage value convertible capacitance value, with the respective to Testing capacitance periodically between a voltage source that is constant in its voltage value and the discharge circuit is switched at a constant frequency, d a d u r c h e k e n n n e i c hn e t that the is in the discharge circuit (position NE of u, R2) adjusting voltage value via an integrating filter arrangement (R3, C2) the evaluation device (DVA) is supplied as a measured value and that the time of its Evaluation is chosen so that it is related to the switching frequency and the residual ripple of this measurement voltage resulting from the filter dimensioning in one and the same range within each period and in each case synchronously with the switching frequency lies. 2. Circuit arrangement according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the measurement time within each period of the measurement voltage defining area is determined by the immediate vicinity of that flank, after half the period, based on the charged state of the to be checked Capacity when switching back to the discharge circuit arises. Circuit arrangement according to Claim 1, d u r c h g e n n z e i c h n e t that the given range by the duration of the Connection to the charging voltage source with the exception of the switchover time determined until the almost complete charge immediately following period is. 4. Circuit arrangement according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the measuring voltage is fed to an analog-to-digital converter (AD) that this is derived from the switching frequency and the evaluation time signaling pulse can be triggered and that its output signals from a process the measured values with regard to the subsequent functions to be linked to them Facility (DVA). 5. Circuit arrangement according to claim 4, d a d u r c h g e k e n n notifies that the device processing the subsequent functions (DVA) the number and order of the inspections and these inspections are initiated in each case.