DE2135308C3 - Circuit arrangement for measuring the duration and the distortion of pulses - Google Patents

Description

and is connected to the other power source during the part of the secondary pulse in which the primary pulse is no longer present. After the secondary pulse has ended, a rotary selector separates the capacitor store from the power sources. The charge stored on the capacitor can then be queried with the aid of a ballistic galvanometer. It represents a measure of the pulse distortion. With this circuit arrangement, at least two contacts each are required to represent the primary and secondary pulse. In addition to the contacts mentioned, there is at least one other contact, e.g. B. from a rotary selector, so that the customer generator does not immediately lose its remaining charge after the secondary pulse has subsided.The reloading of the capacitor by the two power sources takes place depending on a non-linear function, which results in different residual charges depending on the absolute value of the reloading times with the same time differences .

To linearize the charging current curve of a capacitor store, in another known arrangement, which is used to measure the duration of pulses, a pentode used (US-PS 25 06 124). Of the One pole of the capacitor store is connected to the control grid and the other pole to an anode voltage divider connected. Due to the negative feedback from the anode to the control grid that the Capacitor causes the charging current of the capacitor to remain approximately constant. However, this circuit arrangement cannot be used to measure the pulse distortion use, since the capacitor is not connected to two current sources delivering opposite currents can be switched on

When converting analog signals into pulse code modulated signals, it is common to use the output signal the trigger stage assigned to the code element of the highest order with the help of a /? C element Control voltage for adjusting the mean value of the amplitude weighting to the mean value of the amplitude to win the analog signal (FR-PS 13 66 812). In order to achieve shorter settling times, a known device instead of an ÄC-member a capacitor, one-sided at a fixed potential and the other side is connected to two constant current generators, one of which is effective during the working state of the flip-flop and charges the capacitor and the other during the resting state of the flip-flop is effective and discharges it (DE-PS 12 89 104).

The invention is based on the object, the duration and the distortion of pulses, which by only depending a contact can be represented, to be measured with an accuracy which is not influenced by the measuring device depends only on the type of display and its accuracy

According to the invention, this object is achieved in that two constant current generators are used as the current source are used, their outputs with each other and with one pole of the capacitor store are connected, the other pole of which is connected to a fixed potential and for pulse duration measurement only one of the constant current generators during the pulse time of the pulse to be measured or the pulse times of the pulse series to be measured is switched on and the one constant current generator for pulse distortion measurement during the entire pulse time of the primary pulse or the pulse times of the primary pulse series and the other constant current generator throughout the pulse time of the secondary pulse or the pulse times of the secondary pulse series is switched on

Since the pulse distortion can be both positive and negative, depending on whether the primary pulse is longer or shorter than the secondary pulse, a voltmeter would have to be used to display the pulse distortion can be used with a middle zero position, which is then only used for the pulse duration measurement in the positive Making better use of the area could be exploited as there are no negative times Display instrument is achieved according to a development of the invention in that the capacitor store before the pulse distortion measurement can be charged to a bias voltage by means of a switch, which approximately in the middle between the fixed potential and the maximum achievable with the pulse duration measurement

Voltage is present at the capacitor store

Switching the constant current generators on and off can be accomplished particularly easily according to an embodiment of the invention that as Constant current generators the collector-emitter paths of two transistors are used, which through Corresponding control voltages at the base can be switched to saturated and blocked states are and their emitters via resistors at operating voltages with respect to the fixed potential on Capacitor stores of opposite polarity are connected.

In this case the maximum voltage to which the Capacitor memory can be charged during pulse duration measurement by the operating voltage of the corresponding constant current generator determined. Accordingly, there is an advantageous development of the invention characterized in that the bias voltage for the capacitor store at a voltage divider between the fixed potential and the operating voltage of the switched on during the pulse duration measurement Constant current generator is tapped.

The pulses to be measured are generally in the form of voltage or current jumps Reference voltages may be at a different level than the fixed potential of the capacitor store and the operating voltages of the constant current generators. To take this into account and also to enable measurements of pulses of different polarity, e.g. B. the voltage jumps

on a normally open contact and on a normally closed contact or the pulse times and the inverse pulse times, So the pause times, it is provided according to a development of the invention that the control inputs of the Constant current generators amplifier, switch and / or inverter stages for amplitude and phase adjustment are connected upstream.

The advantages achieved by the invention are in particular that time and time difference measurements be made with a measuring circuit

can so that there is only one connection of the measuring circuit to the pulse generator or to another point to be tested in the pulse-controlled system and the actuation of switching means, which can work program-controlled, requires in order to switch from a pulse

series the pulse and pause times of the individual pulses and the distortion between the primary and secondary pulse to eat. Instead of the individual pulse duration and distortion, it is possible to

wand also measure the mean duration and distortion of a series of pulses. For this only the original impulse has to be used or the original pulse series can be applied to the measuring circuit; Auxiliary kitties are not required. So can, for example, in telephone exchanges during the course of a series of dialing pulses, Important times for line selectors are measured and stored in separate, also switchable capacitor stores be directed:

1. The time from the beginning of the first election impulse to the application of the end-of-election sign,

2. the time from the end of the last election pulse to the end of the end-of-election signal,

3. the duration of the pause between the end of dialing signal and the start impulse with immediate participant reporting,

4. the duration of the start impulse.

By switching, other impuisserie can also be used, e.g. for direct dial transmissions Times are measured and saved separately, these are:

1. The time from the end of the last election impulse to the application of the end-of-election sign,

2. the duration of the end-of-election signal,

3. the duration of the pause between the end of dialing signal and the start impulse,

4. the duration of the start impulse.

By further switching operations, the times in which individual contacts, e.g. B. the A contact, the eA contact and the z-contact are closed or open on average, and the difference determine between the respective times of two contacts (pulse distortion). The readings occur in analog form and are stored in analog form, so that - unlike with digital processes, no intermediate value is lost.

An Adsfahningsbeispiel the invention is shown in the drawing and will be described in more detail below. It shows
F i g. 1 a block diagram,

F i g. 2 shows a practical implementation of the circuit arrangement according to the invention.

The arrangement of FIG. 1 consists of two constant current generators 16 and 17, each via a resistor 15 and 18 to different operating voltages of +20 V and -20 V are connected. The operating voltages are at a reference potential related from zero, from opposite polarity. The outputs of the constant current generators 16 and 17 are jointly connected to one pole of a capacitor store 22, the other pole of which is connected to the reference potential Zero is connected. The capacitor store is also connected via an impedance converter 23 very high input resistance and low output resistance with a voltage meter 24 connected. A voltage divider is located between the reference potential zero and the voltage source for +20 V. of two equal resistors 20 and 21. Its center tap is via a button 19 with connected to the capacitor store 22. The control inputs the constant current generators 16 and 17 are shown in FIG. 1 to the outputs of one inverter stage each 13 and 14, the inputs of which lead to sockets 6 and 8. The inverter stages are used for this 13 and 14 only for amplitude adjustment, i. H. their phase-reversing property is in arrangement from F i g. 1 is taken into account, but a phase reversal is not absolutely necessary at this point. In parallel with the socket 6, another inverter stage 10 is connected to the input of the inverter stage 13, whose input type is a socket 7.

The pulses that have zero or negative potential during the pulse duration are applied to socket 6 have e.g. B. the voltage jumps at a normally open contact 1 connected to zero pulses to be measured reversed polarity supplied, z. B. the voltage jumps at a connected to +20 V. Normally open contact or - as shown - at a normally closed contact 2 connected to zero. For measuring the normally closed contact the socket 7 is designed as a switching socket. The pulses are fed to sockets 6 and 8, whose mutual distortion is to be measured. where at socket 6 the primary pulses and at socket 8 the secondary pulses are applied.

The arrangement works as follows. To measure how long the «-contact i spent Impulse lasts, becomes the one-sided connected to zero «Contact 1 connected to socket 6. As long as contact 1 is open, the inverter stage receives 13 An input voltage of + 20 V via the resistor U and emits an output voltage of zero. The constant current generator 16 is designed in such a way that in this case it blocks the inverter stage 13 is zero on the input side and outputs + 20V. The constant current generator 16 is now switched to the working state and charges the capacitor store 22 with a current of +20 V / resistance 15 on. Because of the constant current, the voltage on the capacitor store 22 increases linearly the time in which the «contact 1 is closed. After the contact has opened, the voltage measuring instrument shows 24 a voltage, the level of which is proportional to the duration of the contact closure 24 can therefore be calibrated directly in time units. Before a new measurement is made the memory content of the capacitor store 22 is deleted again, for example by a brief connection with zero effected by a reset button 25 or by the same control means that the trigger the next measurement.

To fe: deliver how long a normally closed contact opens the relevant / - contact 2 with the switch socket 7 connected. As long as the contact is still closed there is zero at the input of the inverter stage 10, at its output and thus at the input of the inverter stage 13 a voltage of +20 V and thus again the blocking potential at the input of the constant current generator 16 NuIL opens the r-contact 2, so the inverter stage receives 10 a voltage of +20 V on the input side via the resistor 9 and therefore emits zero, whereupon the inverter stage 13 supplies an output voltage of +20 V which the constant current generator 16 in the working state switches The voltage that the capacitor store 22 reaches is the one to be measured The opening duration of the r-contact 2 is directly proportional and is displayed by the voltage measuring instrument 24

The measuring range can be switched over by that several graded resistors 15 are provided, one of which by a range switch one at a time is connected to the constant current generator. Since you have the setpoints of the to be measured Knowing times, it is easy to select the appropriate area before the measurement. Of special The expansion of the measuring range is of interest when determining the mean value of the pulse times of a A series of a limited number of pulses. Here-

at are the times of the individual impulses corresponding Voltages are summed up by the capacitor store 22, and the final value gives the total duration again, with a certain and known number of impulses a derivative or - at Appropriate calibration of the voltage measuring instrument 24 - allows the mean value to be displayed.

To measure the pulse distortion, the a contact 1 delivering the primary pulse is connected to the socket 6 and the fr contact 3 delivering the secondary pulse is connected to the socket 8. In addition, a contact or other switch 5, which connects the contact I to the / C relay 4 which actuates the Ar contact 3, is closed. The K relay is connected to any relay supply voltage LJr. As long as the a-contact 1 is open. the constant current generator 16 is blocked as described above. As long as the Ar contact 3 is open, the constant current generator 17 is also blocked, since the inverter stage is connected to -20 V via the resistor 12 and accordingly emits zero on the output side and the constant current generator 17 is designed in such a way that it can only be operated by a control voltage of -20 V can be switched on.

Before the start of the measurement, the button 19 is now pressed and the capacitor store 22 is set to the voltage charged at the center tap of the voltage divider 20, 21 of + 10 V.

The pointer of the instrument 24 thereby moves into the middle position, which is the value zero in the display scale for the distortion measurement. If the a-contact 1 closes now, the constant current generator is activated

16 switched on and charges the capacitor store 22 further. At the same time the / ^ relay receives 4 current and picks up with a certain delay. After the delay time has elapsed, the Ar contact 3 closes and occupies the input of the inverter stage 14 with zero, whereupon the inverter stage 14 has an output voltage of -20 V and thus the constant current generator 17 switches on. The one from the constant current generator

17, which is determined by the operating voltage of -20 V and the resistor 18, which is the same size as the resistor 15, is exactly opposite to the current output by the constant current generator 16 at the same level and thus cancels it. Consequently, no current flows into the capacitor store 22 during the time in which the a contact 1 and the Ar contact 3 are both closed, and the voltage across the capacitor store remains at the level reached during the pull-in delay of ^{the A - -ReUiS 4.} If the a contact 1. opens, the AT relay 4 drops out with another delay. Between the opening of the a contact 1 and the opening of the Ar contact 3, only the constant current generator 17 is now switched on, and its current recharges the capacitor store 22 to negative values. If the drop-out delay of the K-relay 4 is just as long as its turn-on delay before, the voltage at the capacitor store 22 goes back to the amount of the bias voltage of +10 V, and a pulse distortion of ± 0 is displayed only a part of the voltage exceeding +10 V is reduced, and a voltage between +10 V and +20 V is obtained, which is displayed by the instrument 24 as the corresponding positive distortion time. If, on the other hand, the drop-out delay is longer than the pull-in delay, the voltage at the capacitor store 22 drops below the bias voltage of +10 V, and a value between + 10 V and zero is obtained, which is displayed by the instrument 24 as the corresponding negative distortion time.

If not single impulses, but impulse series are examined with regard to their distortion, the result is the sum of the respective distortion times which, given a known number of pulses, provide information about the mean distortion there. The scale for the distortion measurement on the instrument 24 can always be

ίο be calibrated with a constant number of impulses, that it directly reproduces the distortion attributable to a single pulse.

In Fig. 2 is a practical embodiment of FIG Invention shown, namely in F i g. 2a the two

is the constant current generators 16 and 17 together with their Control shown! and in Fig. 2b, those at points I to III connects to Fig.2a, several capacitor stores 22/1 to 22/4 with the impedance converter 23 and the voltage measuring instrument 24.

The constant current generator 16 in Fi g. 2a is controlled via an inverter stage 13, which consists of three im Switching operation of working transistors consists. When contact 1 is open, the first Switch transistor saturated by the current flowing through resistor H, the second as a result locked and the third saturated again, so that the voltage zero occurs at its collector. Through this the pnp transistor of the constant current generator 16 is blocked, and no current flows to terminal II.

If contact 1 closes, the first switch transistor blocks, the second is saturated and the third blocked, and a current flows through its collector resistor, which the pnp transistor of the constant current generalor 16 brings into the conductive state. At connection II, which leads to one of the capacitor stores 22/1 to 22/4 in Fig.2b, now flows in from the position of the range switch 26, with which the resistance IS is selected, more dependent constant Current in the respectively connected capacitor store 22. This current charges the in the idle state on a Voltage from -20 V charged capacitor storage to zero.

In order to measure the opening time of a normally closed contact 2, it is connected to the switching socket 7.

Then, as long as the normally closed contact 2 is still closed, the transistor of the inverter stage 13 is located upstream inverter stage 10 in the blocking state; the first and third switch transistors of the inverter stage 13 are as a result saturated and the pnp transistor of the

Constant current generator 16 locked when opening the Normally closed contact 2, the transistor of the inverter stage 10 goes due to the now supplied via the resistor 9 Base current into saturation and blocks the first and third switch transistor of the inverter stage 13, whereby the pnp transistor of the constant current generator 16 is switched on. The same Conditions result from the measurement on a normally open contact placed against a negative voltage 2/1. which is connected to a socket 7/1. There here the negative voltage is fed directly via the contact 2/1 to be measured, the socket 7/1 is without Switch built up.

The primary pulse is used to measure the pulse distortion supplying contact 1 with the socket 6 and the secondary pulses supplying contact 3 with the Socket 8 connected. Contact 1 switches as above was described in the time measurement, the Konstantstromgerator 16 a for the duration of its closure.

230 235/25

The constant current generator 17 is via an inverter stage 14 connected to socket 8 with two switch transistors 14/1 and 14/2. When contact 3 is open is, the switch transistor 14/1 is saturated, since it is supplied with base current via the resistor 12. At the The collector of the transistor 14/1 is thus zero voltage, and a voltage difference across the Zener diode 27 of 40 V. The Zener diode has a Zener voltage of only 30 V and thus carries current, which means the transistor 14/2 is saturated. At its collector there is a voltage corresponding to the emitter voltage of -40 V, which blocks the npn transistor of the constant current generator 17 closes the contact 3, it blocks transistor 14/1, the collector voltage of which now assumes a value of -20V. The voltage difference at the Zener diode 27 is thereby reduced to 20 V, whereby the Zener diode is blocked will. This also blocks transistor 14/2 and the npn transistor of the constant current generator 17 now receives a base current via the collector resistance of the transistor 14/2, which turns it into the conductive State brings Now a constant current, the level of which is determined by the resistor 18, flows in Direction from connection II to the -40 V operating voltage source. The resistance 18 is just as large as the resistance IS switched on for the measurement of the distortion. That is why it is also from the constant generator 17 supplied current is the same as the current of the constant current generator 16. As a result, the Terminal II flowing current of the constant current generator 16 through the flowing away from terminal II Current of the constant current generator 17 compensated exactly, and the downstream capacitor storage 22 does not receive any charging current during the closing time of the two contacts 1 and 3, contact 1 opens before contact 3, the capacitor store in the time up to the opening of the contact 3 by the current of the constant current generator 17 to -40 V reloaded.

The capacitor 22/1 in FIG. 2b is connected to the connection point II for measuring the distortion. He is connected on one side to a fixed potential of -20 V and is activated by pressing key 19 via the Voltage divider 20, 21 to a voltage of - IO V charged. Since the right connection of the voltage measuring instrument 24 is at - 20 V (the upper voltage divider resistor is small compared to the lower one).

the instrument indicates a voltage of +10 V in the middle zero position. This tension increases during the first phase of the distortion measurement, in which contact 1 is closed and contact 3 is open is, towards +20 V, since the capacitor store 22 is now charged towards zero, then remains in the second Phase in which both contacts are closed remains unchanged and continues during the third phase if contact I is open and contact 3 is still closed is, back again, theoretically up to a final value of -20 V, because the capacitor 22/1 is discharged towards -40 V. In practice, however, the instrument does not show any voltages smaller than OV, corresponding to a voltage on the capacitor 22/1 of -20 V, since such distortion values lie outside the tolerance range anyway.

The memory content of the capacitor 22/1 in F i g. 2b is deleted after completion of one measurement or before the start of the next by means of a contact 25/1 of a reset relay (not shown), ie the capacitor 22/1 is charged to -20V. In addition to this capacitor 22/1, further capacitors 22/2 to 22/4 are provided, which have control contacts b. c I, d and e of control relays, not shown, can be switched on either or according to the program. They are used to save up to four individual values when measuring the time on a series of pulses. They are controlled according to a program selected by means of a switch. Since such a program can be derived from the respective application and a corresponding relay control can be implemented without further explanations, the related parts have been omitted from the drawing in order to facilitate understanding of the measuring principle.

A switch 28 is used to sequentially connect the capacitors 22/1 to 22/4 to the impedance converter 23 to connect and thus to display their memory contents. A field effect transistor circuit is used as the impedance converter 23 with an input resistance of about 680 ΜΩ used for a service life the queried voltage values of several minutes ensures If the values are read and that The respective program is switched off or switched over, takes place via contacts 25/2 to 25/4 of the

Control relay automatically deletes the memory content of the capacitors connected by the program.

For this jj ^ sheet of drawings

Claims (5)

Claims: 13, 14) are connected upstream for amplitude and phase adjustment. 1. Circuit arrangement for measuring the duration and the distortion of individual pulses as well as the average pulse duration and the average pulse distortion of a short-term series a limited number of pulses in which a capacitor store is connected to the outputs of two Current sources and can be connected to a high-resistance voltage measuring instrument, wherein the current sources supply currents in opposite directions and one during the part of the pulse time of the primary pulse, in which the secondary pulse is not yet present, is applied to the capacitor and the other during that part of the pulse time of the secondary pulse in which the primary pulse is no longer pending, is connected to the capacitor and the remaining voltage is on the capacitor is evaluated as a criterion for the pulse distortion, characterized in that that two constant current generators (16, 17) are used as current sources, the outputs of which are connected to one another and to one pole of the capacitor store (22), the other of which Pole is connected to a fixed potential (0), and for pulse duration measurement only one of the Constant current generators (16) during the pulse time of the pulse to be measured or the pulse times of the pulse series to be measured is switched on and for pulse distortion measurement the a constant current generator (16) during the entire pulse time of the primary pulse or the pulse times the primary pulse series and the other constant current generator (17) throughout Pulse time of the secondary pulse or the pulse times of the secondary pulse series is switched on. 2. Circuit arrangement according to claim 1, characterized in that the capacitor store (22) can be charged to a bias voltage by means of a switch (19) before the pulse distortion measurement is the maximum approximately in the middle between the fixed potential (0) and that of the pulse duration measurement achievable voltage (+20 V) at the capacitor store (22) 3. Circuit arrangement according to claim 1 and claim 2, characterized in that as Constant current generators (16, 17) use the collector-emitter paths of two transistors are that by appropriate control voltages at the base in the saturated and in the blocked State can be switched and their emitters are connected to operating voltages via resistors (15, 18) (+ 20 V, -20 V) of opposite to each other with respect to the fixed potential (0) at the capacitor store Polarity are connected. 4. Circuit arrangement according to claim 2 and claim 3, characterized in that the bias for the capacitor store (22) at a voltage divider (20, 21) between the fixed potential (0) and the operating voltage (+ 20 V) of the constant current generator switched on for the pulse duration measurement (16) is tapped. 5. Circuit arrangement according to Claim 1 to Claim 4, characterized in that the control inputs of the constant current generators (16, 17) amplifier, switch and / or inverter stages (10, The invention relates to a circuit arrangement for measuring both duration and distortion of single pulses as well as the average pulse duration and the average pulse distortion for a short time continuous series of a limited number of pulses with a capacitor store at the outputs two power sources and can be connected to a high-resistance voltage measuring instrument, the Current sources currents of opposite direction yeast and the one during the part of the pulse time of the Primary pulse, in which the secondary pulse is not yet available, is applied to the capacitor and the other during the part of the pulse time of the secondary pulse in which the primary pulse is no longer present, to the Capacitor is placed and the remaining voltage on the capacitor as a criterion for the pulse distortion is evaluated. In all areas of application of pulses or series of pulses for control and signaling purposes It happens especially in telecommunications switching technology on the fact that the impulses have certain limit values with regard to their duration and those arising when they are passed on Comply with distortion. Distortion ■ is the difference between the duration of the one further pulse (secondary pulse) triggering pulse (primary pulse) and the duration of the triggered pulse, d. H. of the secondary pulse, understood or the difference between the mean pulse duration of a Primary pulse series and the mean pulse duration of the associated secondary pulse series. Such distortions occur, for example, with an impulse transmission by relays, since their pick-up delay is seldom the same as their drop-out delay the error-free function of impulse-controlled systems can be guaranteed or, in the event of a fault, the Errors can be corrected quickly, it is necessary to adjust the duration and distortion of the pulses occurring there to be checked at certain intervals and, if necessary, by measuring. The mean period and pulse duration of a series of pulses with the aid of time stamp generators is known and storage devices to which the time stamp pulses are controlled by the measurement pulses Gate circuits are supplied, as well as by means of a measuring instrument, the number of stored Timestamp pulses proportional currents or voltages are supplied to measure (DE-PS 12 81 572). In this case, however, a large number of digital storage units are required in order to achieve a high level of accuracy and converter elements for converting the stored digital values into analog display values necessary. In addition, only the pulse duration and not the pulse distortion can be measured. To measure the pulse distortion, a. Scarf- arrangement with two power sources, the currents supply in opposite directions, a capacitor store and a ballistic galvanometer known (DE-PS 7 42 986). The capacitor storage is here via contacts that the primary and Secondary pulses correspond to the two power sources connected in such a way that he during the part of the primary pulse, in which the secondary pulse is not yet present, to which one power source is connected