DE3028972C2 - Method and device for measuring an electrical communication link - Google Patents

Description

Output is connected to a frequency generator FPG . This generator FGP provides at its output a level value of each U2G constant magnitude to the line to be measured NL 2. This level value U2G learns by 2 a '* ■ z corresponding change to be measured line NL. B. its size and is fed as a measured value U2M to the level meter PAfAf at the measuring point AfSr.

The level value UiG present on the line NL i at the end at the remote station GST cannot be used for a direct measurement because its amplitude value depends on the attenuation of the line NL 1. In order to eliminate the undesirable influences of the attenuation of the line NL 1 when measuring the line NL 2 from the remote station GST in the direction of the r> measuring point MST , the frequency fs of the level transmitter P5Af of the measuring point is first converted from the signal UiG by the frequency meter FMG

The measurement can be carried out within a short time and with a high - ¹ "accuracy and a control variable is available at the output of the frequency meter FAfC which reproduces the frequency of the measurement signal from the level transmitter PSAf. This control variable is entered in the frequency generator FPG and controls - '> (synchronized if necessary) to this in such a way that the actual measurement signal U2G it emits with the frequency fe corresponds to the signal UiG of the level transmitter PSAf (within the achievable accuracy), ie fe = fs. In addition, the Jo frequency generator FPG is like this designed that it delivers an output signal, the level of which has a precisely known, predetermined and constant value, in the simplest case such a frequency generator FPG is constructed in the manner of a synthesizer, the output level of which is kept at the precisely defined value with high accuracy the measurement voltage U2G is practically identical in its frequency fe to the measurement signal UiM, which is output by the measuring transmitter PSAf and at the same time * o ensures that a measuring voltage with a predetermined amplitude corresponding to the value U2G is input into the line NL 2 to be measured. This measuring signal is subjected to 2 of a damping and / or phase change or other interference on the line NL and reaches as a signal of the level meter U2M PAfAf. This level meter PMAf can determine the properties of the line NL2 to be determined on the basis of the known (fixed) level value of the signal £ / 2G. If necessary, there may be a connection (in a manner known per se) between the level transmitter PSAf and the level meter PAfAf. In the circuit arrangement according to FIG. 2, the signal coming from the level transmitter PSAf via the line NL 1 is first fed to a Schmitt trigger SAf at the remote station, the output of which is connected to one input of an AND gate UG . The Schmitt trigger SAf converts the incoming sinusoidal signal, whose amplitude fluctuates or changes, into a square-wave signal of constant amplitude, the edges of the square-wave signal being determined by the zero crossings of the measurement voltage UiG coming from the level transmitter. The second input of the AND gate UG is connected to a clock generator TG , which has a very high <"clock frequency (ζ. B. 2 MHz) The output of the AND gate UG controls a down counter RZ in which the clock pulses of the clock generator TG for at least one half cycle (or integer multiples thereof ) of the signal UiG (period measurement). By using a down counter, the counter reading is directly proportional to the frequency. A high counter reading with only a few clock pulses counting down the down counter corresponds to a high frequency fs, while a low counter reading corresponds to a low frequency fs of the signal U 1 G. The one at the end r half-period of fs or integer multiples thereof is reached in digital form (e.g. B. 8 bits parallel) to a digital / analog converter DA 1, at the output of which there is a direct voltage Ug = f (fs) , ie a voltage whose magnitude is directly proportional to the frequency / 's of the measurement signal U IG from the level transmitter PSAf. If an up counter is used instead of a down counter RZ , the situation is exactly the opposite. To get the same relationship Ug = f (fs)? V prhaltpn. is to be provided between the counter and the input of the converter t / fine inversion.

The digital / analog converter DA 1 is also supplied with a reference voltage Ur in a known manner. The direct voltage L ^ is fed to the frequency generator FPG , initially to a voltage-frequency converter UF, which converts the direct voltage Ug into a clock frequency ft , the frequency of which; ι is strictly proportional to the frequency Λ, ie ft = k ■ fs.

This ar! determining the frequency has the particular advantage that it works delay ^f --ei, apart from the low running times within the two DA converter 1 and UF. These properties are particularly important if the level transmitter PSAf according to Fit ;. ! a MepSsignal wobbled in A * r frequency is delivered to line NL 1. The frequency readjustment process takes place immediately after the period measurement and is completed before the next measurement. In this case, a pause (e.g. half a period of fs) is used within which the readjustment processes for the frequency fs can be completed. However, it is also possible to work without a break if the counting result of the down counter RZ is transferred to an intermediate memory (not shown here) which then controls the converter DA 1. While this control is being carried out, the next counting process can immediately follow to be carried out on the previous ones.

The accuracy of the clock frequency ft and thus the frequency fe at the output of the frequency generator ^ FPG is essentially dependent on the linearity of the two converters DA I and UF. If the frequency fe at the output of the frequency generator FPG is to be phase-locked to the input frequency fs , then an additional control device (phase-locked loop - not shown here) must influence the converter i / F in a manner known per se.

In the above arrangement, the inversion was achieved already from the outset by the features of the down counter instead of a down counter is RZ RZ other hand, a forward counter is used, then the necessary inversion can z. B. can also be made in digital-to-analog converter DA 1 in such a way that it delivers a low output DC voltage UG for a large value on the digital side and vice versa.

converter L / Feine inverting in such a way that a ni ° drige clock frequency is supplied at a high input voltage Ug and vice versa. Finally, it is also possible to use other arrangements (e.g. subtractors) for the inversion.

The clock signals at the output of the voltage-frequency converter LlF are fed to a counter ZL which serves as a series-parallel converter and whose output is connected to the input of a sine table ST . At high frequencies fs and thus high values of ft, the counter ZL counts quickly and, based on a unit of time, is full more quickly than at low values. With the next clock pulse that follows, the counter starts again at zero, etc. The counter ZL generates the bit pattern (e.g. 8 bits in parallel) for a sine table ST, at the output of which there is a count value that encodes the desired frequency reproduces. A digital-to-analog converter DA 1 is controlled with this bit pattern, the analog output signal of which is smoothed in a low-pass filter 7V and fed to an amplifier VE. The output signal at the low-pass filter TP has a fixed amplitude value independent of frequency. The amplifier VE is set to a fixed gain value.

At the output of the frequency generator circuit FPG there is thus a level LJ 2G , the frequency fe of which is equal to fs and thus equal to the frequency of the level transmitter PSM of the measuring point M57 '. Furthermore, U2G is set to a fixed level value and thus supplies a defined measurement voltage for the line NL 2.

It is also possible to set a predetermined, preferably integer, but fixed ratio between the frequency fs on the one hand and the frequency fe on the other hand. For example, fe = η · fs can be chosen, where η can preferably represent an integer or a fraction. The value η can be determined by suitable measures in the conversion area z. B. with DA I or with UF or also with DA 2 fixed. It remains constant at least for a number of measuring processes and can be set or changed from the measuring point MST, if necessary via remote control.

According to one shown in FIG. 3 shown modification of the * · embodiment according to FIG. 2 it is also possible to enter the count value of the down counter /? Z (or an up counter) into a programmable digital frequency divider PFT. At the output of this Tpiler, which can be set in its partial ratio \ / x «; prhiili

²ⁿ one also has a clock frequency ft which corresponds to the clock frequency ft of the converter i7F from F i g. 2 corresponds. As a programmable divider z. B. using a microcomputer SAB 8080, the programmable divider SAB 3253 from Siemens can be used.

² ~ "> Details on the structure and operation of SinustaDellen can be found in DE-PS 27 01 859.

In a modified embodiment, the conversion of the period measurement into the frequency / e done by a microprocessor.

1 sheet of drawings

Claims (22)

Patent claims: 1. Method for measuring an electrical communication link using a level transmitter and a level meter, which are each switched on at the near end (measuring point) of the communication link, with a defined level value being fed in at the far end (counterpart) for measuring in the direction of the near end , characterized in that at the far end (GST) of the communication link first a frequency measurement is made, which determines the frequency of the signal (UiG) coming from the level transmitter (PSM) that a frequency generator (FPG) is controlled based on this frequency measurement, the one constant output level (U 2G) outputs, wherein the Ziirn to the measured Nachricruenübertragungsstrekke (NL 2) from the frequency generator (FPG) emitted eigenOiche measuring signal (U2G) 'm its frequency in a predetermined fixed ratio coming from the level transmitter (PSM) signal (U \ G) stands. 2. The method according to claim 1, characterized in that the signal coming from the level transmitter (PSM) is swept in frequency. 3. Procedure according to a; of the preceding claims, characterized in that the measurement signal (U2G) generated at the far end (GST) is emitted for all measurement frequencies with the same output level. 4. Verfai ren according to one of the preceding claims, characterized in that a period measurement of the signal (UiG) coming from the measuring transmitter (PSM ) is carried out as the frequency measurement. 5. The method according to any one of the preceding claims, characterized in that the period duration measurement is done by counting down. 6. The method according to any one of claims 1 to 4, characterized in that the period duration measurement made by counting up and an inversion in the subsequent processing is carried out. 7. The method according to any one of the preceding claims, characterized in that the signal (UiG) coming from the level transmitter with the frequency fs and the actual measurement signal (U2G) with the frequency fe are related to each other in the relationship fe = η ■ fs , where η an integer or a fraction. 8. The method according to any one of the preceding claims, characterized in that at a distance At the end, the frequency generator fF / tyd is also synchronized. 9. The method according to any one of claims 4 to 8, characterized in that after each period measurement there is a pause of at least half a period until a new measurement is taken he follows. 6Q 10. The method according to any one of claims 4 to 8, * characterized in that after each period measurement the measurement result is stored in a buffer and then the next measurement is carried out, preferably without a break will. 11. Device for measuring an electrical communication link using a level transmitter and a level meter, which are each attached to the near end (measuring point) of the communication link, with a defined level value being fed in at the far end (counterpart) for measuring in the direction of the near end is, characterized in that a frequency measuring device (FMG) is provided at the far end of the communication link, which determines the frequency of the signal (UiG) coming from the level transmitter (PSM) , that the frequency measuring device (FMG) has a frequency generator operating at a constant output level (U2G) (FPG) controls, and that the power delivered to the message transmission path (NL2) from the frequency generator (FPG) actual measuring signal (U2G) in its frequency in a predetermined fixed ratio to the next from the level transmitter (PSM) signal (U lG; stehi. 12. The device according to claim 11, characterized in that the signal coming from the level transmitter (PSM)! (UiG) and the measuring signal (U2G) supplied by the frequency generator (FPG) are swept at the frequency. 13. Device according to one of claims 11 or 12, characterized in that the measurement signal (U2G) of the frequency generator (FPG) supplies the same output level for all measurement frequencies 14. Device according to one of claims 11 to 13, characterized in that the output signal generated by the frequency measuring device (FMG) and containing the respective frequency value for controlling a voltage-frequency converter 15. Device according to claim 14, characterized in that the voltage-frequency converter (UF) emits clock signals (ft) which, via a counter (ZL), control a digital sine table (ST) which emits a constant output level and which is an analog / digital converter (DA 2) and a low-pass filter (TP) and possibly an amplifier (VE) are connected downstream. 16. Device according to one of claims 11 to 15, characterized in that in the frequency measuring device (FMG) the frequency is determined via a measuring device for determining the period of the signal (U 1 φ ) coming from the level transmitter (PSM). 17. Device according to claim 16, characterized in that that a time counter is provided to determine the period. 18. Device according to claim 17, characterized in that a down counter (RZ) is provided to determine the period duration. 19. Device according to claim 17, characterized in that when using an up counter subsequently an inversion is provided. 20. Device according to one of claims 17 to 19, characterized in that with digital counting devices (RZ) these are followed by a digital / analog converter (DA 1), the analog output voltage (Ug) of which the voltage-frequency converter (! // ^ controls. 21. Device according to one of claims 17 to 19, characterized in that the counting device (RZ) controls an adjustable divider (PFT) whose output signals are fed as clock signals (ft) via a counter (ZL) to the sine table (ST). 22. Device according to claim il, characterized in that the frequency generator (FPG) is designed as a synthesizer. The invention relates to a method for Measurement on an electrical communication link using a level transmitter and a level meter, each of which is connected to the near end (Meßstcüe) of the communication link at the far end (counterpart) to measure in the direction of the near end defined level value is fed in. When from the far end (remote station) to the near end (measuring point) in communication links is to be measured, a particular problem arises in that the Measurement signal with a predetermined level must be entered into the line to be measured. However, since the level transmitter at the near end, i.e. at the measuring point is set up, the signals coming from the level transmitter meet at the remote station with a through the respective line entered a reduced amplitude value. Special measures must therefore be taken be taken to ensure that a signal from the remote station into the line to be measured can be entered with a specified level. This is known from DE-PS 22 17 209 Measuring device achieved in that in the area of the counterpart a control device in the form of a adjustable amplifier is provided, which readjusts the received level until a desired setpoint has been reached In order to achieve precise and easily reproducible level values in the A specially processed signal is used on the sending side to reach the remote station. which also includes two auxiliary AC voltages that are filtered out at the remote station and to form i'.er control variable for setting the adjustable amplifier are used. It is also known (DE-OS 28 23 837), in a method for determining the temperature coefficient the line attenuation of cables a measurement signal with a first measurement frequency and with a defined feed the first level at a measuring point into a first pair of wires and from this to another measuring point derive a second measurement signal with a constant frequency difference. The second measurement signal is via a so second pair of wires sent back to the one measuring point, this second measuring signal one through the Has frequency conversion caused level jump. The frequency conversion takes place here for prevention of disruptive near-end crosstalk effects. It is also still known (DE-AS 23 34 680), in a method for measuring the frequency-dependent attenuation of telephone lines for measuring the line attenuation of the Remote station to the measuring point at the remote station a remote-controlled switchable and different To use frequencies switchable or automatically scrolling level transmitter with constant level. The remote control takes place via a separate data channel. b> The invention is based on the object of substantially simplifying the processing of the metisignal, especially in the area of the far end (ie the remote station). According to the invention, this is achieved in a method of the type mentioned at the outset in that a frequency measurement is first carried out at the far end of the nadirieh'vm'b ^ iri-isurigisi'ek · ki · iid. vü ^ iühe Sz Frequency of the signal coming from the level transmitter determines that a frequency generator is controlled on the basis of this frequency measurement, d \. '. r eV ^ n emits a constant output level, whereby the frequency of the actual measurement signal delivered by the frequency generator to the communication link is within a predetermined frequency has a fixed relationship to the signal coming from the level transmitter. In this way, all difficulties are avoided, which z. B. by means of a Amplifier occur, at the same time it is ensured that the frequency generator at the remote station generated output levels! one regardless of the characteristics of the one coming from the level transmitter Line (and also regardless of the level properties of the level transmitter itself) always constant Has level value. The measurement from the remote station to the measuring point can lomit what the Level value is concerned, with an accuracy unaffected by time and by the respective line conditions be performed. The frequency measurement itself can be carried out on the one hand with simple means and on the other hand can be realized with a high accuracy. The invention also relates to a device for measuring an electrical communication link using a level transmitter and a level meter, each at the near end (Measuring point) of the communication link are attached, with the far end (counterpart) to Measuring in the direction of the near end, a defined level value is fed in, which is characterized by this is that a frequency measuring device is provided at the far end of the communication link which determines the frequency of the signal coming from the level transmitter, that the frequency measuring device controls a frequency generator that works with a constant output level, and that the the actual measurement signal emitted by the frequency generator in its Frequency is in a predetermined fixed ratio to the signal coming from the level transmitter Other developments of the invention are given in the subclaims. The invention is explained below with reference to drawings. It shows F i g. 1 shows the structure of a communication link in a block diagram with a measuring device according to the invention; F i g. 2 Details of the circuit structure of the measuring device in the area of the far end (remote station); F i g. 3 shows a modification of the circuit structure according to FIG. 2. In FIG. 1, the measuring point at the near end is designated by MST and the counterpart at the far end is designated by GST . The measuring unit is equipped with a level transmitter PSM of conventional design, which is connected to a first message transmission line NL 1 (output _H ^- port UiM). Furthermore, the measuring section blowing a level meter PMM on which to be measured to a second * cr Nachrichtcnübertragungsleitung NL'i ungesih'ossen \ s: iAusgangsspannur.g U2 \ * The remote station CST has a frequency meter FMG connected to the line NL i, whose