DE102004003350A1 - Transmission line part echo creation procedure filters and differentiates complete echo with sign or result used to define echo start points - Google Patents

Abstract

A transmission line part echo (c1-n) creation procedure filters (5) and differentiates (4) the complete echo (b) and uses the sign of the result to iteratively determine successive partial echo start points from the positive points within preset intervals. Independent claims are included for equipment and a computer program using the procedure.

Description

method and apparatus for forming partial echo signals from a total tech signal to estimate a reflection factor of a far echo signal and for determining of errors of a transmission line by evaluation of component echo signals The present invention relates to a method and apparatus for forming partial echo signals from a Gesamttechosignal, which for example on a transmission line was measured, to estimate an absolute reflection factor of a far-end part signal as well for determining electrical properties such as a Short circuit or interruption of the transmission line by evaluation of partial echo signals.

Such a transmission line is, for example, a telecommunication line leading from an exchange to an end user, such as a telephone line. It is desirable to be able to determine errors in the line such as short circuits or a break in the line (short or open error) from the exchange. From the DE 102 26 350 A1 For example, it is known to measure a line by Time Domain Reflectrometry (TDR), measuring the echo of a transmitted signal and using it to echo cancel Measurement can be used.

It It is an object of the present invention to provide a method and to provide a device which allows one, for example Total tech signal measured in partial echo signals using this TDR method which, for example, reflections of different Represent locations of the line such as short circuits or breaks. Furthermore, it is an object, a method for estimating the absolute reflection factors of far echo signals of these component echo signals to provide, that is, of component echo signals which are not within the device, of the starting from the measurement was made. Finally is it is an object of the invention, a method and an apparatus to provide, which allows, based on component echo signals Determine errors in a data line.

These Tasks are solved by a method according to claim 1, a method according to claim 13 or a method according to claim 15 and by a device according to claim 25, claim 27 or claim 29. The dependent claims define advantageous or preferred embodiments of the method or the device. additionally A computer program product according to claim 31 is provided.

• 1. Bestimmen des nächsten Zeitpunktes der Vorzeichenfunktion, bei dem diese einen positiven Wert des Vorzeichens angibt,
• 2. Setzen dieses nächsten Zeitpunktes als Anfangszeitpunkt eines Teilechosignals
• 3. Überspringen eines vorgegebenen Zeitraums
• 4. Bestimmen des nächsten Zeitpunktes der Vorzeichenfunktion, bei dem diese einen negativen Wert des Vorzeichens angibt
• 5. Sprung zu Schritt 1 ausgehend von diesem Zeitpunkt, um einen Anfangszeitpunkt eines weiteren Teilechosignals zu bestimmen.

According to the invention, for forming partial echo signals from a total echo signal of a transmission line, it is proposed to filter the overall echo signal to produce a filtered overall echo signal, differentiate the filtered overall echo signal, and form a sign function of the differentiated filtered echo signal indicating its sign. In order to determine the start times of the partial echo signals, the time course of the sign function is examined beginning with its beginning according to the following steps:

• 1. determining the next time of the sign function, in which this indicates a positive value of the sign,
• 2. Set this next time as the start time of a part echo signal
• 3. Skip a given period
• 4. Determine the next time of the sign function, in which this indicates a negative value of the sign
• 5. Jump to step 1 from this point in time to determine an initial time of another part-echo signal.

One predetermined time interval of the total tech signal from each of the so certain start times of the component echo signals is then respectively assigned to a partial echo signal.

Prefers Before or after filtering, the absolute value of the total tech signal is determined educated.

If thereby two successive starting times of component echo signals have a shorter time interval than the predetermined time interval, the component echo signal is preferably from the first of these two start times until the second of these start times from the total tech signal educated, and for the remainder of the predetermined time interval becomes the component echo signal set to zero.

With Such a method makes it possible in a simple way To form a total tech signal part echo signals, which then for any purpose can be further processed. For example, you can Line errors can be detected, or it can also conduction properties for the transmission be determined.

The Gesamttechosignal can, for example, by cross-correlation one over chende data line sent sending signal with the corresponding reflected transmission signal or sampled echo signal are formed. The sampled echo signal corresponds for example to coefficients of a simultaneously used circuit for echo cancellation.

A Device which transmits the transmission signal, the measurement of the Echo signal and the formation of the cross-correlation performs as a measuring device for the determination of the total technology signal are called.

The Filtering is preferably carried out via a filter which the fed him Signal averages, for example, by always for a certain value Maximum of the supplied Signal over a certain period of time (so-called median filter). However, there are in principle other filters, which an averaging perform the overall tech signal, usable.

To This filtering is preferably a noise reduction, the Threshold is a least significant bit of the absolute value of the Total tech function corresponds. After differentiation, one can second noise reduction be made.

Of the given period preferably has a length of 1/2 to 2/3 of a typical Length of one Partial echoes in the overall tech signal.

It can be a maximum number to consider Part returns are given to a complexity of a subsequent evaluation to be kept within limits.

The first of the component echo signals from the total tech signal represents a near echo which, for example, on a hybrid of the measuring device and therefore at the beginning of the transmission line occurs. The rest Partial echo signals from the overall echo signal are distant echoes. To estimate a absolute reflection factor of such a remote echo is proposed according to the invention, both the damping of the distant echo in relation to the Nachecho as well as its temporal delay to determine based on the near echo. Then with the help of a typical assumed attenuation value per unit length assumed to be known the line and a presumed known typical time delay value per unit length the line the absolute value of the reflection factor of the far echo calculated. The sign of the reflection factor of the distant echo becomes determined by comparing the signs of far-end echo and near-echo.

to Determination of line faults on the basis of determined part echoes a faulty transmission line, which have been determined, for example, as described above these parts echo signals detected on the error-free transmission line Reference partial echo signals compared. It is proposed according to the invention, a Amplitude including the sign of the amplitude and a temporal delay each detected component echo signal and reference component echo signal determine and determine which of the component echo signals with a the reference part echo signals in both amplitude and sign as also coincide in the time delay determine which of the component echo signals with one of the reference component echo signals in the time delay, but not in amplitude or in their sign, determine which of the detected parts echo signals with no match the reference part echo signals in the time delay, and determine which of the reference part echo signals has no the parts echo signals coincide in the time delay. Depending on These findings will be a possible Line fault determined. These line faults can cause short circuit errors, interrupt errors or an increased one damping in the pipeline.

The in the determinations determined parts echo signals and reference signal echo signals can in a match list, an amplitude list, a new list or a list of misses accordingly the respective statement registered, so classified. additionally can be a reflection factor of each measured part echo signal from the Sign of the respective amplitude determined and in the determination taken into account by line faults become. Furthermore, it can be considered be whether in an attempted connection setup signals from a device at a remote end of the transmission line were obtained.

at For reasons of efficiency, this method may be advantageous, parts echoes with reflection factors which fall below a certain absolute value, not to be considered.

With In such a method it is possible to have different line errors for example, from an exchange to determine what an analysis of the respective data line simplified.

The Invention will now be described with reference to the accompanying drawings using preferred embodiments explained in more detail. It demonstrate:

1 a schematic of an apparatus for determining component echo signals from a Ge samtechosignal and to determine the delay, the sign and the amplitude of these parts echo signals,

2 a preprocessing of a sampled echo signal to produce the overall tech signal,

3 a block diagram of the block for determining the component echo signals from the Gesamtechosignal from 1 .

4 an illustration of an operation of a filter 7 out 3 .

5 an illustration of the operation of the device of 3 .

6 an illustration of the through the device of 3 determined starting times of component echo signals,

7 an illustration of the formation of partial echo signals according to the invention,

8th an illustration of determining a delay of a partial echo signal,

9 an illustration of the determination according to the invention of the reflection factor of a far echo partial echo signal,

10 an exemplary embodiment for the determination of a line fault by comparing and classifying determined part-echo signals with reference-part echo signals,

11 an inventive classification of detected component echo signals and reference component echo signals in lists,

12 a flowchart for splitting into lists of 11 , and

13 a flowchart for the inventive determination of various line errors from the lists of 11 and 12 ,

1 shows a device according to the invention 1 for forming partial echo signals c1,..., cn from a total tech signal b of a transmission line, for example for telecommunications. In this case, a sampled echo signal a by a preprocessing unit 2 converted into the total tech signal b. A processing unit 3 forms partial echo signals c1,..., cn and associated start times d1,..., dn of these component echo signals. calculation units 4 in combination with a filter 5 then finally calculate the associated delay signals e1, en, enmax and amplitude values f1, ..., fn,..., fnmax of the partial echo signals thus formed. Of course, this calculation can be made with several parallel calculation units 4 as well as sequentially with a single calculation unit.

In the following, the functions of the individual blocks will now be described 1 be shown or explained in more detail.

In 2 is the functioning of the preprocessing unit 2 out 1 shown in more detail. The upper graph shows a typical sampled echo signal a over time t, tmax indicating a maximum time value up to which sampling was taken. Such a signal is z. B. in the adjustment or calibration of a device for echo compensation, as in the already mentioned document DE 102 26 350 A1 is described. In this case, a transmission signal is transmitted and scanned from a received signal, the reflected transmission signal again. Meanwhile, the overall audio signal of interest represents only a small portion of this signal. The pre-processing unit now performs, for example, a cross-correlation of this sampled echo signal a with the transmit signal to obtain the overall tech signal b, which is shown in the lower graph of FIG 2 is shown. As can be seen, this total tech signal b comprises three component echo signals c1, c2 and c3, 3, the first component echo signal always being the so-called near echo, which is obtained by reflection in the apparatus which performs the measurement of the sampled echo signal a.

It It should also be noted that the sampling usually takes place in discrete time steps takes place, so that the signals a and b strictly speaking no continuous Curves, but are composed of a plurality of samples, which is also characterized by a sample index instead of the time t can be.

The processing unit 3 out 1 now separates these individual parts echo signals c1, c2, .., as in 3 Darge presents. The Gesamttechosignal b is initially a block 6 which forms the absolute value of the individual samples of the overall tech function b. The signal thus generated becomes a mean value filter 7 supplied, the operation of which will be explained in more detail later and which supplies as it were a smoothed Gesamttechosignal g. This is followed by a first block 8th for noise suppression with a threshold value n1.

The signal thus generated becomes a differentiator 9 supplied, wherein the differentiation in the z-representation can be represented by the transfer function 1 - z ^-1 .

The differentiated signal h thus generated becomes a second block 10 for noise suppression with a second threshold n2 supplied.

A sign unit 11 forms the sign function i of the signal thus generated, which in turn in a block 12 is used to determine start times d1, ..., dn, ... of the component echo signals. For this purpose, a period parameter k can be specified. In a block 13 For example, these start times d1, ..., dn together with the overall tech function b are used to form the part-echo signals c1, ..., cn, each having a length or a number of samples, which are represented by a time interval parameter 1 is predetermined. The operation of the processing unit 3 will be explained in more detail below.

In 4 becomes the function of the mean filter 7 out 3 (Median filter) shown schematically. The upper graph exemplifies samples of the overall tech signal b, of which block 6 the absolute value was formed. The mean value filter 7 Now, to form a value of the filtered signal g, the maximum of the absolute values of the total tech signal is formed in an interval following the corresponding value of the total tech signal, as indicated by the arrows 14 hinted tet. In the present example, the maximum of five values is respectively formed to determine a value of the filtered signal g, that is g (t) = max * (abs (b (t)), abs (b (t + 1)), ..., abs (b (t + 4))) being as a step size between the samples 1 , that is, a unit time interval was assumed. The number of values from which the maximum is formed should be chosen such that, on the one hand, the oscillations of the overall tech function are smoothed, on the other hand, echoes which have small amplitudes and are in the vicinity of large-amplitude echoes are not canceled out. For example, instead of five values as in the example, the number of values used may be three.

Such a mean value filter 7 is particularly suitable for signals which echoes with low amplitudes, since it is always searched for maxima of the total tech signal and therefore relatively small maxima can be detected. In principle, however, it would also be conceivable to use an FIR filter with correspondingly adapted coefficients.

After the mean value filter 7 is a first block 8th intended for noise reduction. This removes samples with very small values, which were generated only by noise in the sampling signal a in order to avoid errors in the further processing. For this purpose, all values of the filtered total tech signal g, which are smaller than the first threshold value n1, are set to 0, ie
if g (t) <n1 then g (t) = 0.

The value n1 must be chosen so that on the one hand the noise is eliminated as well as possible and on the other hand part echoes with small amplitude are not deleted. The values are available as digital signals, a favorable value for n1 corresponds approximately to the value of the least significant bit of the signal g. For example, if the bit width 23 is normalized (1 bit for the sign, 22 bits for the amplitude) and the maximum value of the sample signal is normalized to 1, n1 = ^22-22 = 2.5 × 10 ^-7 . In general, a threshold value n1 adapted to the amplitude of the sampled values can be used, ie the threshold value n1 can be selected adaptively as a function of a respective echo amplitude.

• 1. Es wird der erste Wert des Vorzeichensignals i gesucht, welcher „+1" ist (Pfeil A). Dies ist der Anfangszeitpunkt d1 des ersten Teilechosignals. Von diesem Zeitpunkt d1 wird, wie durch den Pfeil B angedeutet, ein Zeitraum übersprungen, welcher durch den Zeitraumparameter k angegeben ist. Dies bewirkt, dass keine zwei Echos detektiert werden, wenn es nur ein Echo mit relativ langer Anstiegszeit gibt. Zudem kann dies durch Rauschen verursachte Fehler reduzieren oder ausschalten. k hat bevorzugt einen Wert zwischen 1/2 und 2/3 der typischen Länge eines Teilechosignals in dem Gesamtechosignal.
• 3. Ab dem Ende dieses durch den Zeitraumparameter k vorgegebenen Zeitfensters wird der nächste Zeitpunkt gesucht, an dem die Vorzeichenfunktion i den Wert –1 annimmt.
• 4. Ab diesem Zeitpunkt, das heißt dem ersten Zeitpunkt, an dem das Vorzeichensignal i –1 beträgt, wird der nächste Zeitpunkt gesucht, an dem das Vorzeichensignal i positiv ist, d. h. +1, (dargestellt durch den Pfeil D). Dies ist der Anfangszeitpunkt d2 des zweiten Teilechosignals.
• 5. Ausgehend von dem Anfangszeitpunkt d2 wird mit Schritt 2. weitergemacht.

After the differentiator 9 will do a second noise reduction in a second block 10 for noise suppression with a second threshold n2 performed to avoid errors in the subsequent determination of the sign. Analogous to the first block 8th for noise reduction is according to the rule
if abs (j (t)) <n2 then j (t) = 0
For a dynamics of, for example, about 125 dB between the largest and the smallest echo amplitude and again for a normalized sampling signal a, ie a sampling signal whose maximum amplitude has been normalized to 1, n2 should be about 2 ^-1 In 5 is shown schematically as in block 12 the starting times d1 ... dn of the various component echo signals are determined. As the highest is in 5 again the total tech signal b is shown, below which follows the signal g after the mean value filter 7 , In the third line, the sign signal i is shown, which in the sign unit 11 is formed from the signal j, which substantially corresponds to the differentiated signal g. The signal i has the value +1 if the signal j is positive, that is, if the signal g has a positive slope, and the value -1, if the signal g has a negative slope accordingly. If the signal g = 0, then the sign signal i = 0. Now, the following steps are performed to determine the d1 ... dn:

• 1. The first value of the sign signal i which is "+1" (arrow A) is searched for, which is the starting time point d1 of the first part-echo signal From this time point d1, as indicated by the arrow B, a time period is skipped This will cause no two echoes to be detected if there is only one echo with a relatively long rise time, and this may reduce or eliminate noise caused by noise turn. k preferably has a value between 1/2 and 2/3 of the typical length of a component echo signal in the overall tech signal.
• 3. From the end of this time window specified by the period parameter k, the next time is sought at which the sign function i assumes the value -1.
• 4. From this point in time, that is, the first time point when the sign signal i is -1, the next point in time at which the sign signal i is positive, ie +1, is searched (represented by the arrow D). This is the start time d2 of the second partial echo signal.
• 5. Starting from the start time d2, step 2 , kept going.

This method ends when either the value tmax is off 2 is reached or a predetermined maximum number nmax of echoes was found. Too high a number of found echoes may make subsequent processing unnecessarily complicated without achieving higher accuracy of a result. The maximum number nmax is therefore set according to the particular application.

6 shows an example of a total tech function b with four parts echo signals and the corresponding determined start times d1-d4. d1 can also be 1, it corresponds to the start time of the Nahecho.

In block 13 out 3 Finally, the corresponding partial echo signals c1,..., cn are determined on the basis of the initial times d1,..., dn determined in this way. This is in 7 shown schematically. Each component echo signal consists of the specified number 1 of samples. That is, first, for each component echo signal c1, ..., cn, the sample is used at the corresponding start time d1, ..., dn plus the samples following l-1; the unit interval is again used as time unit. Each partial echo signal ci, i = 1 ... n ... nmax is thus formed according to the following rule: ci (t) = b (di + t - 1) for t = 1, ..., l

• 1. Für das letzte so ermittelte Teilechosignal mit dem Anfangszeitpunkt = dnmax kann es passieren, dass dieses Echo über den betrachteten Zeitraum der Funktion b (0 bis tmax) hinausreichen würde. In diesem Fall kann beispielsweise als Ausgleich der Beginn des Teilechosignals vorgezogen werden und das Teilechosignal gemäß ci(t) = b(t + tmax – l) für di > tmax – l + 1gebildet werden. Diese Verschiebung muss dann allerdings gegebenenfalls später bei einer Berechnung der Verzögerung des Teilechosignals berücksichtigt werden. Eine andere Möglichkeit wäre es, die am En de des Teilechosignals „fehlenden" Werte mit Nullen aufzufüllen.
• 2. Für di + l – 1 > d(i + 1) würden sich die so erzeugten Teilechosignale überlappen. Um bei einer späteren Auswertung Fehler zu vermeiden, wird der überlappende Teil des ersten dieser Echos auf 0 gesetzt. Dies ist in 7 veranschaulicht. Im oberen Graphen ist ein Ausschnitt des Gesamtechosignals b dargestellt. Ein erstes Teilechosignal soll zum Zeitpunkt t = di beginnen, ein zweites Teilechosignal zum Zeitpunkt t = d(i + 1). Nach der oben erläuterten Vorschrift würde das erste dieser Teilechosignale ci bis t = di + 1 – l erreichen und somit in dem dargestellten Beispiel über den Anfang des folgenden Teilechosignals hinausreichen. Der überlappende Bereich ist mit E bezeichnet. Im unteren Graphen ist das Teilechosignal ci dargestellt. Der überlappende Bereich E wurde auf 0 gesetzt.

It is advantageous to consider two special cases:

• 1. For the last partial echo signal thus determined with the starting time = dnmax, it may happen that this echo would extend beyond the considered period of the function b (0 to tmax). In this case, for example, as compensation, the beginning of the component echo signal can be preferred and the component echo signal in accordance with ci (t) = b (t + tmax - l) for di> tmax - l + 1 be formed. However, this shift must then be taken into account later, if necessary, in a calculation of the delay of the component echo signal. Another possibility would be to fill in the values "missing" at the end of the partial echo signal with zeros.
• 2. For di + l - 1> d (i + 1), the component echo signals thus generated would overlap. In order to avoid errors in a later evaluation, the overlapping part of the first of these echoes is set to 0. This is in 7 illustrated. The top graph shows a section of the overall tech signal b. A first partial echo signal should start at time t = di, a second partial echo signal at time t = d (i + 1). According to the above-explained rule, the first of these component echo signals would reach ci to t = di + 1-l and thus extend beyond the beginning of the following component echo signal in the illustrated example. The overlapping area is denoted by E. The lower graph shows the partial echo signal ci. The overlapping area E has been set to 0.

As in 1 are calculated for the preferred application of the decomposition into component echo signals, namely the adjustment of line errors, delays and amplitudes of the individual component echo signals.

The calculation of the absolute delay en of a partial echo signal cn is in 8th shown schematically. The uppermost graph shows the partial echo signal cn. This function determines the envelope shown in dashed lines and uses the time of the maximum as the relative delay qn of this component echo signal. In the middle of the time scale of the overall technology function b is shown. t = 1 of the parts echo function cn corresponds to this, as indicated by an arrow 15 indicated, their initial time dn, qn corresponds, as by an arrow 16 indicated, the point t = qn + dn - 1. To calculate the absolute delay en of the component echo signal cn, it must also be considered that by the formation of the cross-correlation in the preprocessing unit 2 a delay relative to the sampled echo signal a whose time scale is shown below in 8th is drawn, which is indicated by an arrow 17 is indicated. The absolute delay is then determined by means of an adder 18 from the delay on the time scale of the total tech signal b and this by the arrow 17 indicated delay calculated.

For the above described case that the starting point of the echo, which otherwise exceed tmax would, has been moved forward, of course, this must be considered accordingly become.

The Amplitude fi of each component echo signal corresponds to the value at the maximum the envelope, where here the sign taken into account should be to distinguish positive from negative reflection factors to be able to. Thus, fi represents the signed amplitude.

As a preferred application example, the generated part echo signals should be used to check if there is a short circuit or open fault (English short or open fault) in a data line. Partial echo signals generated by such errors have reflectivity factors near 1. Therefore, for such an effect, partial echo signals, which are caused by reflections with a low reflection factor, are not interesting. Such parts echo signals are through the filter 5 out 1 in order to facilitate a subsequent interpretation and to increase the reliability of the interpretation results. The filter 5 takes two steps: It estimates the absolute value of the reflection factor of each component echo signal, which was caused by a distant echo, that is, by a reflection in the line, and removes those component echo signals, which have a low reflection factor.

For the estimation of the absolute value of the reflection factor of the component echo signals, the near echo or near-end component echo signal c1, which is always the first of the component echo signals, is used as a reference. The delay vi with respect to the near-end partial echo signal c1 of a partial echo signal ci is in principle by vi = T · (ei - e1), where T corresponds to the actual duration of a unit sample time interval of the signals a, b and c.

The attenuation of this partial echo signal ci relative to the near-end partial echo signal c1 in decibels results in wi = 20 · log (| f1 / fi |).

in principle depends on this attenuation wi of the properties of the line, the absolute value of the reflection factor, but also on the type of pulses used and possibly overlays several echoes. Indeed may be the echo removal, in particular due to the overlay from the damping can not be calculated with certainty. It is possible, however, the Absolute value of the reflection factor from these values vi and wi At least estimate the use of typical values of the line.

In 9 the calculated values are shown schematically. 19 refers to the near-end echo, 20 the remote echo to be examined. An arrow 21 indicates the attenuation, j indicates the delay between the two echoes.

Typical values for a transmission line are, for example, 10 dB / km for the attenuation and 5.5 μs / km for the delay. The typical attenuation wli caused by the transmission line ("loop") is thus wli = vi × 10 dB / 5.5 μs.

The actual attenuation wi is generally greater than this value, since the absolute value of the reflection factor is generally less than 1. The estimated value for the absolute value of the reflection factor ri is thus ri = wli - wi = vi · 10dB / 5.5 μs - 20 · log (| f1 / fi |).

The filter 5 out 1 removes, for example, all parts echo signals for which ri <-20 dB applies.

For the other parts echo signals, as in 1 shown on the right, creates a first list, which includes the delay ei and the amplitude (including sign) fi for each component echo signal. Starting from this first list is then as in 11 and 12 presented a classification made in four more lists. Using the lists thus created with a reference list, which includes delays eir and amplitudes fir for the error-free transmission line, such line errors can be evaluated and determined. Such an evaluation is exemplary in 10 shown.

The upper graph shows the amplitude values of the reference list 22 plotted over time. The reference list 22 includes three entries, where the amplitude values f1r and f3r are positive and the amplitude value f2r is negative. A measurement on the same but faulty transmission line gives z. For example, the list 24 , also with the values of three partial echo signals. These values are plotted over time in the lower graph. The two lists are in a comparison unit 23 compared. It will be noted that the first two echoes match, while the third echo is in the list 24 has a lower delay and a greater amplitude than the third echo of the reference list 22 (arrows 26 . 27 ). Since the amplitude of the third echo of the list 24 relative to its delay is relatively large (this is, as described above, through the filter 5 out 1 ensured), it can be concluded that this is a short circuit or interruption error, which in turn depends on the sign of the amplitude f3. This will be from another unit 25 evaluated, the corresponding error code is added together with the corresponding delay of the echo f3 of the error in a list 28 written.

It It should be noted that such a relatively complex measurement and Evaluation procedure only carried out should be, if after a fatal error in a connection over the transmission line a rebuilding of the connection fails. For example, send this a switching center (COT, Central Office Terminal) so-called C sounds on a terminal (CPE, Customer Premise Equipment). Only if then no so-called R tones returned may be a short circuit or interrupt error, and the debugging procedure should be performed.

Below is the evaluation of the lists 22 and 24 be systematized to detect errors. In principle, when comparing the reference list 22 with the first list generated by measuring the overall echo and determining the component echo signals 24 Four different cases occur, as in 11 is shown. In the upper graph of 11 are the amplitudes of three partial echoes of the list 24 plotted at the times e1, e2 and e3, in the lower diagram correspond to three amplitudes of the reference list 22 at the times e1r, e2r and e3r.

The first echo signals of both lists agree both in time (e1 = e1r) and in amplitude (f1 = f1r); this value will be in a match list 29 entered. The second part echo signals of the lists 24 and 22 coincide in time (e2 = e2r), but have different amplitudes (f2 ≠ f2r). The corresponding values of the list 24 be in an amplitude list 30 entered. The third echo of the list 24 has no match in the reference list. The corresponding values are in a new list 31 entered. The third echo of the reference list 22 has no equivalent in the list 24 , the corresponding values of the reference list will be in a wrong list 32 entered.

In 12 is a possible flowchart for such a division into the four lists 29 to 32 shown. Starting point is step 33 , In step 34 will all entries of the reference list 22 into the list of errors 32 transfer. It can also be the first echo of the reference list 22 in the match list 29 be registered. In the following step 35 the next or the first pass of the loop becomes the first entry of the first list 24 selected for editing. In step 36 a check is made as to whether the delay of this entry to be processed is the first list 24 with a delay of the list of errors 32 matches. If not, it will go along arrow 44 to step 38 passed, in which this entry to be edited the first list 24 is added to the new list, and then directly to step 42 jumped. If yes, in step 37 Check if the amplitude of this entry to be edited is the first list 24 coincides with the corresponding amplitude of the entry of the miss list with which it coincides in the delay. If the amplitudes are the same, it will be along arrow 46 to step 40 passed, in which this entry to be edited in the match list 29 is registered. If the amplitudes do not match, it will be along arrow 47 to step 39 in which this entry to be edited the first list 24 into the amplitude list 30 is registered. In both cases, then in step 41 the corresponding entry which is in the delay with this entry of the first list to be processed 24 matches, from the list of errors 32 away. In step 42 Finally, it checks whether the entry to be edited is the last entry in the first list 24 was. If yes, will be over arrow 49 to the end 43 gone the procedure, the procedure according to arrow 48 at step 35 with the next entry of the first list 24 continued.

It should be noted that even small changes in the line, for example due to temperature fluctuations, or even the finite resolution of the digital values used, are small differences between the values for delays and amplitudes between the list 22 and the list 24 can effect. It is therefore beneficial to step in 36 out 12 consider two delays equal if they do not differ by more than one delay threshold. Likewise, it is beneficial in step 37 consider two amplitude values as equal if they do not differ by more than a predetermined amplitude threshold.

13 shows a flowchart of a method with which by means of the lists thus created various types of errors, including interruption and short circuit errors of a data line can be determined. As an additional criterion it is used, whether the already mentioned R-tones were received from the remote end during connection establishment. In addition, both absolute values and the sign of reflection factors, which are determined as already described, are included in the decision.

at the branches means a "J" on a respective connecting arrow, that this path is taken when the "question" in a respective diamond-shaped box with yes is answered, "N" is accordingly the arrow taken when this question answers with no becomes.

The procedure starts at step 50 , In step 51 it is checked whether the reference list (reference chen 22 in 10 ) has more than one entry. An entry, namely that for the near echo, is always present and is therefore not considered here. If yes, go to step 52 If not, go to step 53 ,

In step 52 Checks whether both the list of errors and the new list are empty. If yes, go to step 55 If not, go to step 54 ,

In step 53 it checks if the new list is empty. If yes, go to step 55 if not, will go in step 76 detected that there is either a short circuit fault or an interrupt error or a terminal is not connected to the far end of the data line. Since the reference list contains only a single entry here, no more precise statement can be made.

In step 54 It is checked whether a delay value of the echo in the new list is smaller than all the delay values in the reference list except the near echo. If so, get in step 63 if not, go to step 56 ,

In step 55 it is determined if the amplitude list is empty. If yes, will step in 70 found that no changes or abnormalities were detected in the line. If not, go to step 57 passed. In step 56 it is checked whether the delay value of the first echo in the new list is greater than all delays of the echoes in the reference list. If so, get in step 59 If not, go to step 58 passed. In step 57 it is checked if the match list is empty except for the near end part echo signal. If yes, will step in 71 it is determined that the line has increased damping, if not, it becomes step 75 in which it is stated that the data do not allow a reliable conclusion on a specific error. In step 58 Checks whether the new list contains only a single echo. If so, get in step 59 If not, then it goes to the step already described 75 jumped.

In step 59 a check is made as to whether the list of errors is empty. If so, get in step 60 If not, go to step 61 passed. In step 60 it is checked whether the delay values of the echoes in the new list are greater than the delay values of all other echoes in all other lists. If so, get in step 62 if not, proceed to the step already described 75 jumped.

In step 61 a check is made as to whether the delay values of all the echoes in the error list are greater than the delay values of echoes in the new list. If so, get in step 63 if not, turn to step 75 jumped.

In step 62 it is checked if the amplitude list is empty. If so, get in step 64 if not, go to step 75 jumped. Likewise also in the step 63 checks if the amplitude list is empty. If so, get in step 65 if not, go to step as well 75 jumped.

In step 64 It is checked whether R-tones, that is a response from the far end of the line was missing in a connection. If so, get in step 66 if not, go to step 75 jumped. Likewise, in step 65 Checks if R-tones are missing when connecting. If so, get in step 67 if not, go to step as well 75 jumped.

In step 66 It checks whether the absolute values of the reflection factors in the new list (the amplitude list and the list of errors have already been found to be empty) are close to 1. If so, get in step 68 if not, go to step 75 jumped. In step 67 it is also checked whether the absolute value of the reflection factors of the considered echoes in the new list is close to 1 (the amplitude list is again empty). If so, get in step 69 if not, go to step 75 ,

In step 68 will check if the in step 66 considered reflection factor is positive. If yes, will step in 72 found that a terminal is not connected, if not, will go to step 75 passed. Likewise, in step 69 Check if the in step 67 considered reflection factor is positive. If yes, will step in 73 found that there is an interrupt error, if not, in step 74 determined that there is a short circuit fault. After any of the findings in the steps 70 to 76 will the procedure in step 77 completed.

It is still to be noted that an unconnected terminal and a Interrupt error at the end of the data line in principle not can be distinguished In essence, these two cases are identical.

Of course that is in 13 The flow chart shown is just one of many possible ways to analyze the different parts echo signals or the different lists. In particular, the checks that need to be made to arrive at a particular conclusion may also be made in a different order. Of course, if only certain errors are to be searched, then only the corresponding branches of the flowchart need to be selected 13 be taken into account. In principle, it is also conceivable to omit some checks, whereby the result would then be subject to a higher uncertainty. Finally, it is also possible to dispense with the explicit structure of the lists and, as it were, implicitly directly in the process of 13 make.

Claims (31)

A method of forming partial echo signals (c1, c2, ...) from a total tech signal (b) of a transmission line, wherein the total tech signal (b) is filtered, differentiating the filtered total tech signal (g), wherein a sign function (i) of the differentiated one is formed, which indicates a sign of the differentiated filtered total echo signal (h, j), wherein for determining start times (d1, d2,...) of the component echo signals (c1, c2, examines the time course of the sign function (i) according to the following steps: determining the next time the sign function (i) in which this indicates a positive value of the sign, setting this time as a start time (d1, d2, ...) of a partial echo signal (c1, c2, ...), 3. skipping a given time period (k), determining the next time point of the sign function (i) after the predetermined time period (k) at which this one nega indicates the logical value of the sign, starting from this next time step by step 1 and repeating steps 1-5 to determine the start time of a further part-echo signal, and wherein in each case a predetermined time interval ( 1 ) of the total technology signal from a specific starting time (d1, d2,...) is assigned to a component echo signal (c1, c2,...). Method according to claim 1, characterized in that that before or after the filtering, an absolute value (d) of the total tech signal (b) is formed, and that this absolute-value-formed total-tech signal (d) for the further process steps are used. Method according to claim 1 or 2, characterized that in the case that two consecutive component echo signals overlap, the overlapping one Part of the first of these two parts echo signals is set to 0. Method according to one of claims 1 to 3, characterized that the total tech signal (a) by a cross correlation of a Transmission signal with a sampled echo signal (a) is formed. Method according to claim 4, characterized in that the sampled echo signal (a) corresponds to the coefficient of an echo canceling device. Method according to one of the preceding claims, characterized in that the filtering by a mean value filter ( 7 ) is made. Method according to one of the preceding claims, characterized characterized in that the filtered total tech signal (g) is noise filtered becomes. A method according to claim 7, characterized in that For noise filtering, all values of the filtered total tech signal (g) whose amplitude is smaller than a predetermined first threshold (n1) is to be set to zero. Method according to one of the preceding claims, characterized characterized in that the differentiated filtered total tech signal (h) is noise filtered. Method according to claim 8, characterized in that that in the noise filtering of the differentiated filtered total tech signal (h) all values of the differentiated filtered total tech signal (h), whose amplitude is smaller than a predetermined second threshold (n2) are set to zero. Method according to one of the preceding claims, characterized characterized in that the predetermined period (k) is 1/2 to 2/3 of a typical length a partial echo signal (c1, c2, ...) is. Method according to one of the preceding claims, characterized characterized in that the method is at most a predetermined number (nmax) determined by the component echo signals (c1, c2, ...) and the steps 1 to 5 at most go through until the determination of the predetermined number of start times become. Method for estimating a reflection factor a distant echo of a transmission line, in which a damping of the distant echo in relation to an associated one Nahecho is calculated, where a typical attenuation of the transmission line estimated will, and where the reflection factor is the difference between the typical damping and the damping of the Farewell echoes in relation to the associated near echo is calculated. A method according to claim 13, characterized ge indicates that the typical attenuation is estimated from the difference in near-end delay and far-echo delay, and typical attenuation per line delay time. Method for determining line faults of a transmission line based on this transmission line measured component echo signals and reference component echo signals, which correspond to the component echo signals of the faultless transmission line, in which for each measured partial echo signal has a signed amplitude and a delay is determined become, wherein it is determined which partial echo signals (c1, c2, ...) coincide with a reference signal echo signal in amplitude and delay, in which It is determined which parts echo signals (c1, c2, ...) with a Reference part echo signal in the delay, but not in the amplitude match, in which it is determined which measured partial echo signals (c1, c2, ...) do not coincide with any reference part echo signal in the delay, where found which reference signal echo signals with no measured partial echo signal to coincide in the delay in which Based on these findings, a line fault of the transmission line is determined. A method according to claim 15, characterized in that the possible ones Line fault Short circuit fault, interrupt error and / or one increased damping the transmission line include. Method according to claim 15 or 16, characterized that in addition a reflection factor of the measured partial echo signals is determined. Method according to claim 17, characterized in that that the determination of the reflection factors according to one of claims 13 or 14 takes place. Method according to one of claims 17 or 18, characterized that partial echo signals with a reflection factor, which is smaller is a given value in determining the line error not considered become. Method according to one of claims 15 to 19, characterized that Amplitude and delay the component echo signals (c1, c2, ...), which with a reference part echo match in amplitude and delay, in a match list be registered that amplitude and delay of those parts echo signals, which with a reference signal echo signal in the delay, but do not agree in amplitude, be entered in an amplitude list, that amplitude and delay those partial echo signals, which with no reference signal echo signal to coincide in the delay be entered in a new list, and that amplitude and delay those reference signal echo signals which with no measured partial echo signal (c1, c2, ...) match in the delay, be entered in a list of errors. Method according to one of claims 15 to 20, characterized that in the determination of the line error is additionally taken into account, whether in a Connection via the transmission line Signals from a device at a remote end of the transmission line were obtained. Method according to one of claims 15 to 21, characterized in that the component echo signals (c1, c2, one of the claims 1 to 9 are determined. Method according to one of claims 15 to 22, characterized it is determined that a component echo signal with a reference component echo signal coincides in amplitude, if the difference between the amplitude of the component echo signal and the amplitude of the reference part echo signal is smaller than a predetermined one Amplitude threshold is. Method according to one of claims 15 to 23, characterized it is determined that a component echo signal with a reference component echo signal coincides in the delay, if the difference between the delay of the part echo signal and the delay of the reference part echo signal is smaller than a predetermined delay threshold value is. Device for forming partial echo signals (c1, c2, ...) from a total tech signal (b) of a transmission line, with filter means ( 7 ) for filtering the total tech signal (d), with differentiating means ( 9 ) for differentiating the filtered total tech signal (b), with means ( 11 ) for forming a sign function (i) of the differentiated filtered total tech signal (h, j), which indicates a sign of the differentiated filtered total tech signal (h, j), and with evaluation means ( 12 . 13 ), which are designed in such a way that, for determining start times (d1, d2,...) of the component echo signals (c1, c2,...), they examine the time profile of the sign function (i) according to the following steps: determining the next one Time of the show chenfunktion (i), in which this indicates a positive value of the sign Setting this time as the start time of a part echo signal skipping a predetermined period Determining the next time the sign function after the predetermined period (k), in which this indicates a negative value of the sign, outgoing from that next point on, step by step 1 and repeating steps 1-5 to determine the start time of another part-echo signal, and that each of them has a predetermined time interval ( 1 ) of the total technology signal (b) from a specific starting time (d1, d2,...) to a component echo signal (c1, c2,...). Device according to claim 25, characterized in that that the device to carry out a Method according to one of the claims 1 to 12 is configured. Apparatus for estimating a reflection factor of a far echo of a transmission line, comprising means ( 5 ) for calculating the attenuation of the far echo relative to an associated echo echo, estimating a typical attenuation of the line and calculating the absolute reflection factor from a difference between the typical attenuation and the attenuation of the far echo in relation to the associated near echo. Device according to claim 27, characterized in that the means ( 5 ) are designed to estimate the typical attenuation by forming a difference between a delay of the associated post-echo and a delay of the far echo, and from this difference and a typical attenuation per delay calculate the typical attenuation. Device for determining line errors of a transmission line based on this transmission line measured component echo signals and reference component echo signals, which correspond to the component echo signals of the faultless transmission line, With Means for determining a signed amplitude and a delay for each measured partial echo signal, with means for determining which Component echo signals (c1, c2, ...) with a reference signal echo signal in Amplitude and delay match, With Means for determining which parts echo signals (c1, c2, ...) with match a reference echo signal in the delay, but not in the amplitude, With Means for determining which measured partial echo signals (c1, c2, ...) do not coincide with any reference part echo signal in the delay, With Means for determining which reference signal echo signals with no match the measured partial echo signal in the delay, with funds to evaluate these determinations to determine a line fault the transmission line. Device according to claim 29, characterized in that that the device to carry out a Method according to one of the claims 15 to 24 is configured. Computer program product for determining line faults by means of measured parts echo signals and reference signal echo signals, thereby characterized in that the computer program product on a data processing system a method according to any one of claims 15 to 24 performs.