JPH07143039A - Method and device for measuring crosstalk characteristic of balanced pair cable - Google Patents

Abstract

PURPOSE:To speed up the measurement of the attenuation quantity of a crosstalk in a nearby terminal by setting the multiple pairs of cores to be guide lines, measuring the multiple pairs with a pair as guided lines and setting the other ends of the core lines to be open at that time. CONSTITUTION:The plural lines 2A, 2B,... and 2N are collectively connected to an oscillator 1 to be the guide lines. The guided lines 5 are made one lines as they are, and a level meter 4 measures the attenuation quantity of the crosstalk. At that time, the other ends of the respective lines are set open as they are. When a value measured by the level meter 4 is within the range of a prescribed standard value, the combination becomes satisfactory. Then, one line among the plural lines 2A, 2B,...2N is set to be the guided line again and the guide lines are constituted by the plural remaining lines. Then, similar measurement is repeated and propriety is judged. When the measurement value of the level meter 4 is out of the standard value, the combination becoming defective is measured by setting the guide lines and the guided lines to be 1:1 again.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and apparatus for measuring the crosstalk characteristic of a balanced pair communication cable.

Generally, an insulated conductor (core wire) is gathered and a common coating is formed on the conductor, which is called a cable. A balanced pair communication cable includes, for example, 100 pairs of core wires. Then, one pair constitutes one telephone line. The phenomenon that a signal on one line leaks to another line is crosstalk. What appears in the same direction as the propagation direction of the signal on the induction line is called far-end crosstalk, and what appears in the opposite direction is called near-end crosstalk. Transmission quality Will be a factor that deteriorates.

Therefore, in one communication cable,
It is necessary to check whether or not there is a combination that causes such a crosstalk between the lines included therein, and if there is a combination, take appropriate measures to prevent deterioration of transmission quality.
The present invention relates to a method and apparatus for measuring the crosstalk characteristic of a balanced pair communication cable, which has such a meaning.

[0004]

2. Description of the Related Art Crosstalk is a phenomenon in which a signal is mixed from one line to another line, as described above. Insulation deterioration is considered to be the cause.

FIG. 18 is a block diagram showing a conventional crosstalk measuring method. In the figure, 1 is an oscillator, 2 is an induction line, 3 and 6 are impedances respectively, 4 is a level meter, and 5 is an induced line. As shown in FIG. 18, conventionally, the crosstalk characteristic is that the impedance Z (Ω) at both ends of the induction line (pair of core wires) 2 and the guided line (pair of core wires) 5 is adapted to the frequency f (Hz). ) And lead line 2
Then, a signal of f (Hz) was applied from the oscillator 1, the near-end crosstalk attenuation amount was measured by the level meter 4 of the guided line 5, and evaluation was made based on the result.

19 and 20 are flow charts showing the procedure of such a conventional crosstalk measuring method. That is, FIG.
One flowchart represented by combining FIG. 20 and FIG. 20 shows such a procedure.

Please refer to FIG. 19 and FIG. First, as the parameter setting, if the frequency of the oscillator 1 is set to f (Hz) and there are 100 lines to be measured, the line with the line number 1 as the induction line N and the line with the line number 2 as the guided line M are Set each. Furthermore, the number L of defective line combinations is set to 0 as an initial setting.

Next, in a state of (line 1: 1) between the inductive line N and the induced line M, the near-end crosstalk attenuation amount is measured by a level meter in a state where both ends of each line are terminated by the impedance Z. To do. If the measurement result is TdB, it is judged whether or not it satisfies a predetermined standard. If it is not satisfied, the number L of defective line combinations is increased by 1, and if it is satisfied, it is left as it is. Next, it is judged whether or not the line number of the guided line M is 100 or less. If the line number is less than 100, the line number of the guided line M is increased by 1, and then the measurement is returned to.

If the line number of the guided line M is not 100 or less, the line number of the guided line N is increased by 1 and it is judged whether it is 99 or less. Return to measurement as N + 1. If not
It is judged whether or not the number L of defective line combinations is 0, and if 0, the crosstalk characteristic is good. Here, the value obtained by this measurement (that is, the value measured by the level meter) is defined as the true value of the near-end crosstalk attenuation amount in the sense of the value obtained by the orthodox method.

[0010]

According to the above-mentioned conventional measurement, for each combination of lines composed of the number of lines to be measured, one set of the induction line and the induced line is one set. Are carried out one by one. Therefore, if the number of lines is large for one cable, the required number of measurements will be enormous.

That is, when the number of core wire pairs (the number of lines) is g, to measure the near-end crosstalk characteristic of the cable, _g C
₂ = g! / {2! X (g-2)! } Measurements are required. For example, if the cable is a cable including 100 pairs of cores (lines), the measurement requires 4950 times of measurement.

FIG. 21 is a graph showing the relationship between the number of lines to be measured and the required number of measurements in the conventional crosstalk characteristic measurement. From the figure, the number of measurements increases in a factorial manner as the number of target lines increases.
It will be appreciated that 4950 measurements need to be made when targeting 00 pairs of lines. Therefore, there is a drawback that it takes a huge amount of time to measure the crosstalk attenuation amount.

In addition, in the balanced-pair communication cable that is actually or is about to be operated as a service to be measured, the number of lines having really bad crosstalk characteristics is generally very small, about 0 to 10 out of 4950. Therefore, in order to find a few sets of defects, it was necessary to measure 4950 times, which was very inconvenient.

In addition, when a signal of a predetermined frequency is applied from one end side of the line during measurement, personnel are placed on the signal application side of the line, and the work of reconnecting the cable core wires is required every time the line combination is changed. Needless to say, it is necessary to reconnect the terminating impedance Z (Ω) also on the other end side of the line. Furthermore, the measurement signal application side of the target line is inside the station building, but the other end of the line is outdoors, so workers are required for tasks other than measurement (such as traffic control). Yes, there is a large amount of operation. Therefore, during the measurement period, it is necessary to always allocate personnel to the other end side, and there is a drawback that many operations are required.

In practice, sophisticated measurement techniques are needed to find more combinations with poor crosstalk characteristics within a limited time. In addition, since the cable also has a working line and cannot be measured for a long time, it is difficult to measure the crosstalk characteristic of the whole cable core wire.

Therefore, the object of the present invention is to firstly reduce the time required to measure the near-end crosstalk attenuation amount, and secondly to reduce the operation required for measurement, and as a result, to improve the crosstalk characteristics. It is an object to realize and provide a method and an apparatus for measuring the crosstalk characteristic of a balanced pair cable, which can be quickly measured and evaluated while saving operation.

[0017]

To achieve the above object, in the present invention, when the number of lines to be measured is N (where N is a plurality) among the total number of lines forming a balanced pair communication cable. , A method for measuring the crosstalk characteristics of a balanced pair cable for detecting a combination of lines in which a crosstalk attenuation amount between a certain one of the N lines and another one is less than a certain specified value, or In the device,

Among a plurality of N lines to be measured, by connecting one end of the lines to a common signal source and leaving the other ends of the lines open, A plurality of specific lines are used as induction lines, and a high impedance level meter is connected to one end of any one of the N lines other than the specific plurality of lines, and the other end of the line is opened. An induction line is provided, and at least a step of measuring the near-end crosstalk attenuation amount between the induction line and the induced line with the level meter is included.

[0019]

The near-end crosstalk attenuation amount is measured at 1: 1 (both ends) between the induction line and the induced line, whereas in the present invention, the induced line is the same line, but the induced line is the same. In this case, by connecting multiple lines to the signal source, the required number of measurements is reduced compared to the case where the induced line and the induced line are measured 1: 1. By connecting the measuring device side to all the target lines and automatically changing the line combination, you can save time and effort when changing the combination, and the line side that does not apply the signal is open (impedance). (Not terminated at) to reduce the operation required to terminate at the conventional impedance.

[0020]

EXAMPLES Examples of the present invention will be described below. FIG. 1 is a block diagram showing a characteristic crosstalk measuring method adopted by the present invention. In the figure, the same components as those in FIG. 18 are designated by the same reference numerals. In addition, 2A, 2B, ...
..., 2N are lines. That is, in FIG. 1, a plurality of lines 2A, 2B, ..., 2N are collectively connected to the oscillator 1 to form an inductive line, the induced line 5 remains as one line, and the level meter 4 measures the crosstalk attenuation amount. To do. At this time, the other end of each line is left open without being terminated by impedance.

If the value measured by the 1-level meter 4 in this way is within the range of the predetermined standard value, this combination is good. Next, a plurality of lines 2A, 2B, ...
, 1N of 2N is made to be the guided line again, and the remaining plural lines make up the guiding line, and similar measurement is repeated to judge pass / fail. If the value measured by the level meter 4 is out of the range of the predetermined standard value, this combination is defective. In this case, the defective line and the guided line are set to 1 again. :
Measure at 1. That is, the configuration in which the inductive line is collectively composed of a plurality of lines is disjointed, and the inductive line is measured one by one with each inductive line as an inductive line. Also at this time, the other end of the line is left open without being terminated by impedance.

FIG. 2 is a block diagram showing a crosstalk measuring method used at this time (that is, another characteristic crosstalk measuring method adopted by the present invention). As already mentioned,
The inductive line was made up of a plurality of lines 2A, 2B, ..., 2N all at once.
Each of A, 2B, ..., 2N) is used as a guiding line and the measurement is performed with the preceding guided line 5, and the lines 2A, 2B ,. , 2N are measured.

For the combination which is measured by this 1: 1 line combination and judged to be defective by that, the conventional crosstalk measuring method described with reference to FIG. 18 is carried out again, and the result is finally judged as good. It is the principle operation of the present invention to judge a defect.

In summary, in the present invention, a plurality of pairs: 1 pair [OPEN] → 1 pair: 1 pair [OPEN] → 1 pair: 1 are used in the present invention by using the measurement system shown in FIGS. 1, 2, and 18.
It can be said that the near-end crosstalk attenuation amount is measured in the order of pair [Z (Ω) termination], and a combination (crosstalk line) having a bad crosstalk characteristic and having a standard value A (dB) or less is specified. The standard value A (dB) is a criterion applied to the true value of the near-end crosstalk attenuation amount. Then, the determination criteria A ₁ , A ₂ (d
B) is determined from the correlation between the measurement result of each measurement system and the true value.

First, a regression line is obtained from the measurement results of the measurement system shown in FIGS. 1 and 2, and it is confirmed that the measurement result has a positive correlation with the true value. Move in parallel. Then, at the intersection of the true value A (dB) and the vertical line, 6
Judgment criteria A ₁ , A ₂ (dB) in anticipation of a margin of dB
Determine. Hereinafter, this will be described with reference to FIGS. 3 and 4.

In FIG. 3, the horizontal axis shows the value measured by the conventional method shown in FIG. 18 as the true value, and the vertical axis shows the value measured by the characteristic method according to the present invention shown in FIG. Since this measurement result is an example for the voice band, the frequency f is 1 kHz, the termination Z is 600Ω, and the standard value A is 68.
It is set to dB. As described above, the regression line is obtained from the measurement result, and after confirming that the measurement result has a positive correlation with the true value, the regression line is moved in parallel to the higher risk rate (upward). Then, considering the margin of 6 dB at the intersection with the vertical line of the true value A (dB), the criterion A _{1 is set} to 80.
(DB).

In FIG. 4, the horizontal axis shows the value measured by the conventional method shown in FIG. 18 as the true value, and the vertical axis shows the value measured by another characteristic conventional method according to the present invention shown in FIG. Has been taken. Since this measurement result is an example for the voice band, the frequency f is 1 kHz and the termination Z is 600.
Ω, the standard value A is 68 dB. As described above, the regression line is obtained from the measurement result, and after confirming that the measurement result has a positive correlation with the true value, the regression line is moved in parallel to the higher risk rate (upward). And the true value A
The judgment criterion A ₂ was set to 70 (dB) by allowing for a 6 dB margin at the intersection with the vertical line (dB).

Next, the measurement systems shown in FIGS. 1, 2, and 18 are
A method of measuring the crosstalk characteristic of the balanced pair cable according to the present invention, which is used as needed, will be described with reference to the flowcharts of FIGS. That is, FIG. 5 and FIG. 6 are flowcharts showing the procedure of the method for measuring the crosstalk characteristic according to the present invention when the two are combined into one flowchart.

Please refer to FIG. 5 and FIG. (A) First, the frequency f (Hz) of the applied signal and the termination Z
(Ω) and criteria A, A ₁ , A ₂ (dB) are defined.

Then, as shown in the measurement system of FIG. 1, a signal of f (Hz) is applied with the other ends of the plurality of lines open.
For lines other than the signal application line whose both ends are open, a combination in which the near-end crosstalk attenuation amount is A ₁ (dB) or less is extracted. For example, when targeting 100 pairs of cable core wires,
Core number (# 1 to 99 → # 100), (# 1 to 98 → #
99), ..., (# 1, 2 → # 3), (# 1 → #)
2) 99 combinations.

As a result, the near-end crosstalk attenuation amount is A ₁ (dB)
When there is no combination below, it is evaluated as "good crosstalk characteristics". (B) Next, apply the signal of f (Hz) to the combination extracted in (a) with the measurement system of FIG. A combination in which the end crosstalk attenuation amount is A ₂ (dB) or less is selected.

As a result, the near-end crosstalk attenuation amount is A ₂ (dB).
When there is no combination below, it is evaluated as "good crosstalk characteristics". FIG. 1 shows the combinations selected in (c) and (b).
Combination in which near-end crosstalk attenuation is A (dB) or less in a measurement system in which both ends of 8 are terminated by Z (Ω) (line with poor crosstalk characteristics)
The crosstalk characteristics are evaluated by specifying As a result, when there is no combination in which the near-end crosstalk attenuation amount is A (dB) or less, it is evaluated as “good crosstalk characteristics”.

Next, FIG. 7 is a conceptual diagram showing the concept of a measuring apparatus for carrying out the method for measuring the crosstalk characteristic according to the present invention described above. In FIG. 7, the present measuring device M is of a form that is connected only to the signal application side of the balanced pair communication cable 11, and includes a signal distributor 13, a scanner 14 having a function of switching the measuring core wire, and a terminal board conducting tool. 23, frequency oscillator 1
5, selection level meter 16, control unit 12 (transmission unit 12
S, receiving unit 12R, no access unit 12C), memory 1
7, a level comparator 19, a comparison standard value generation unit 18, a display unit 20, a console unit 21, and a printer 22.

The signal from the oscillator 15 is supplied to the signal distributor 13
Via the transmission unit 12S of the control unit 12 via the scanner 14
The signal is applied to the line (induction line) of the communication cable 11 designated in. The level meter 16 includes the control unit 1
2 is connected to the line (guided line) of the communication cable 11 designated by the scanner 14 by the receiving unit 12R,
Measure the crosstalk attenuation. The no-access unit 12C of the control unit 12 specifies a line (for example, a working line) of the communication cable 11 that is not the measurement target in the scanner 14. The level comparator 16 compares the measured value of the level meter 16 with the standard value from the comparison standard value generator 18, and the defective combination is stored in the memory 17.

Since the induction line and the induced line are controlled by the control unit 12 so as to be sequentially changed, all combinations of the lines to be measured are automatically measured, and the measured data is level-determined by the comparator 19. After that, it is stored in the memory 17. In addition, the terminal board conductor 23 is used to control so as to identify the working line and the vacant line, so that the measurement line can be collectively connected.

The operation procedure of the crosstalk characteristic measuring apparatus shown in FIG. 7 is shown in detail in the flow charts of FIGS. That is, FIGS. 8 to 11 are flow charts showing the operation procedure of the crosstalk characteristic measuring apparatus according to the present invention when all of them are combined into one flow chart.

According to the operation flow of FIGS. 8 to 11, the measurement of the near-end crosstalk attenuation amount and the evaluation of the crosstalk characteristic can be quickly performed with less operation, and the workability is greatly different from the conventional technique.
Here, a case where the crosstalk characteristic of the target cable core wire N (pair) is measured will be described using the operation flows of FIGS. 8 to 11.

In the present embodiment, since the target is the voice band, the frequency f is 1 kHz and the terminating impedance Z is 6.
00Ω, the standard value A is 68 dB, and the judgment criteria A ₁ and A ₂ are 80 dB and 70 dB, respectively.

(A) First, the present apparatus is connected to a communication cable as shown in FIG. 7, and core numbers n (pairs) [a (1), a (2 ), ..., a
(N)], frequency 1 kHz, signal level VdBm, and comparator levels 80 dB and 70 dB.

(B) Next, the number N of core wire pairs (lines) to be measured is obtained by subtracting the number n of core wire pairs not to be measured from the number (99) of cable core wire pairs (lines). ,
The number of guided lines M is 101. Near-end crosstalk attenuation of lines (guided lines) M other than the signal-applied line (induction line) N that is applied to the multiple lines (induction line) N with the other end open and the signal is applied at both ends. Measure the quantity. Here, it is possible to measure all target combinations by sequentially switching the N-1 (group) combinations.

As a result, a combination having a near-end crosstalk attenuation amount of 80 dB or less is extracted from R [dB]. However, when there is no combination in which the near-end crosstalk attenuation amount is 80 dB or less, it is evaluated that “the crosstalk characteristic is good”.

(C) Then, the combination extracted in (b) is further applied with a pair of induction lines and a pair of induced lines, and a signal of 1 kHz is applied with the other end of the induction line open, and both ends are connected. The near-end crosstalk attenuation amount S [dB] of the opened guided line is 70
Select combinations below dB. However, when there is no combination in which the near-end crosstalk attenuation amount is 70 dB or less, it is evaluated that “the crosstalk characteristic is good”.

(D) Finally, with respect to the combination selected in (c), a person having personnel on the receiving end side and terminating both ends at 600Ω and having a near-end crosstalk attenuation amount of 68 dB or less (poor crosstalk characteristic) Evaluate by specifying the line).

(E) When a plurality of frequencies are targeted, a plurality of frequencies and levels of the comparator are set in (a), and (b) to (c) are measured for all the frequencies. , (D), the crosstalk characteristic for each frequency is evaluated.

FIG. 12 is a block diagram in which FIG. 7 is redrawn from the viewpoint of the circuit configuration, that is, a block diagram showing the circuit configuration of a measuring apparatus for carrying out the crosstalk characteristic measuring method according to the present invention. The same parts as those in FIG. 7 are designated by the same reference numerals. For the sake of better understanding of the present invention, an embodiment of the present invention will be described again with reference to FIG.

In FIG. 12, the changeover switch (scanner) 14 is controlled by the controller 12. Switch 1
When 4 is 1, a signal of frequency f is applied to the core wire. When the switch is 2, the crosstalk signal induced in the line is input to the level meter (measuring unit) 16. When 3, the line is opened.

In the standard value generating unit (reference setting unit) 18, crosstalk attenuation amount reference values A1, A2, A in each measurement configuration (described later) at the applied signal frequency are set. For example, the crosstalk attenuation amount reference values A1, A2 and A at the audio frequency f are set to 80 (dB), 70 (dB) and 68 (dB), respectively. These are the numerical values obtained from the experiment, and
As described above, 1 and A2 show the setting history in FIGS. 3 and 4.

In each of the above measurement configurations, the induction line and the induced line are N to 1 and the terminal side is open, and the induction line and the induced line are 1 to 1 and the terminal side is open. Configuration, and the induction line and guided line 1
There are three types of configuration (pair 1) and the terminal side is terminated with a characteristic impedance (conventional crosstalk measurement configuration).

The memory 17 has the following files. A file for recording the combination of the induced line and the guided line to be measured for each measurement condition (this file is shown in FIG. 13. That is, FIG. 13 is an explanatory diagram showing a file configuration of the memory 17 in FIG. 13 (a) is N to 1
FIG. 13B shows a file (when the terminal is opened).
Indicates a one-to-one (terminal open, short circuit) file.
The data such as the guide line number is written after the initial setting. )

A file in which line numbers not measured are recorded (temporary file is also possible). Crosstalk attenuation reference values A1, A2 at the audio frequency f
A file that records A. When there are a plurality of frequencies, the file is a file in which the crosstalk attenuation amount reference values A1, A2, A for each frequency are recorded. (If written in a program, there is no need to create a file)

The control unit 12 determines the guided line and the guided line based on the initial settings and creates the above file.
(Measurement result column is blank). The control of the changeover switch 14 is
The test circuit of N to 1 (terminal open) is formed by operating the changeover switch of the line to be the induction line to the 1 side and the changeover switch of the line to be the guided line to the 2 side.

The induced signal L generated in the guided line is measured by the level meter 16, and the crosstalk attenuation amount L is calculated by a calculation unit (not shown) attached to the level meter 16. The comparison unit 19 compares the crosstalk attenuation amount L with the reference value A1, and when L <A1, the comparison unit 19 outputs, for example, “1”, and the control unit 12
Writes NG (* mark in the previous flowchart) in the measurement result column of the above file.

Next, the changeover switch 14 is controlled to change the combination of the induction line and the induced line, and the next measurement is performed.

The measuring method of the present invention will be specifically described by taking 10 pairs of cables (line numbers # 1 to # 10) as an example. First, the induced line and the induced line are set to n: 1 (the terminal is open), and the crosstalk attenuation amount is measured. Initially, the guided lines are # 1 to # 9 and the guided lines are # 10.

The measured crosstalk attenuation is 90 dB,
Since it is larger than the first crosstalk attenuation amount standard value (80 dB), it is determined that the combination of the guided line (# 1 to # 9) and the guided line (# 10) is good. If the measured crosstalk attenuation is smaller than 80 dB (for example, 70 dB), it is stored in the memory because the combination of the induced line and the induced line may be bad.

Next, the same measurement is performed by changing the combination of the guided lines # 1 to # 8 and the guided line # 9. At the end of this measurement, the guided line is # 1 and the guided line is # 2. It is assumed that the measurement result is as shown in (A1) of FIG. From this measurement result, the next measurement is performed only for the combination of the guided lines # 1 to # 3 and the guided line # 4 (indicated by an underline in A1 of FIG. 14).

Crosstalk attenuation is measured by setting the induction line and the induced line to 1: 1 (the terminal is open). It is assumed that the measurement result is as shown in (A2) of FIG. From this measurement result, the induced line # 1 and the guided line #
In the case of the combination of 4 (indicated by an underline in A2 of FIG. 14), the second crosstalk attenuation amount standard value is 60 dB, and therefore, the combination of the inductive line and the induced line is stored in the memory, which may be bad.

From this measurement result, the conventional measuring method is used only for the combination of the induction line # 1 and the induction line # 4, that is, the induction line and the induction line are one-to-one (terminals are terminated).
And measure the crosstalk attenuation. This crosstalk attenuation is 68d
If it is smaller than B, it can be seen that the combination of the guided line and the guided line is bad.

Above, the description of the embodiment of the present invention has been completed, and the measurement result example will be described below. The crosstalk characteristic of the communication cable was measured using the measuring method according to the present invention. In this example, the crosstalk characteristics between the empty lines in three units (300 pairs) in which 99 pairs, 92 pairs, and 63 pairs are respectively set as the empty lines were measured. The frequency was set to 1 kHz because the target was the voice band.

The procedure and the result will be described below. First, in the measurement system of FIG. 1, a signal of 1 kHz was applied to 5 pairs of inductive lines with the other end opened, and the near-end crosstalk attenuation of the induced line with both ends open was measured for 2234 sets. The measurement result is shown in the graph of FIG.

From this, the near-end crosstalk attenuation amount is 80 dB.
The following combinations were extracted. Next, using the measurement system shown in FIG.
Near-end crosstalk attenuation was measured with the terminal open with the combination of the pair and the pair of guided lines.

From the result, the near-end crosstalk attenuation amount is 70 dB.
The following combinations were selected. Finally, for both combinations selected in step 600
The near-end crosstalk attenuation amount was measured in the Ω-terminated state, and the combination of 68 dB or less was specified to make the entire evaluation.

The conventional method requires 10990 measurements, but when this measurement method was used, 15 pairs of crosstalk lines could be identified by 3500 measurements, and the crosstalk characteristics could be measured and evaluated.

[0064]

As described above, by using the present invention, it is possible to measure the first induction line and the induced line with a plurality of pairs: one pair to reduce the number of measurements, and all the target lines. There is an advantage that the near-end crosstalk attenuation amount can be measured quickly by saving the trouble of re-connecting when changing the combination by connecting all together to automatically change the combination.

The effect is shown as an implementation rate of the number of measurements by the maximum number of lines bundled as an induction line. The implementation rate of the number of measurements refers to the ratio of the number of measurements by the present measurement method to the original number of measurements G (times).

FIG. 16 shows the maximum number of induced lines depending on the number of measurements with the number of target lines as a parameter.
It can be seen that the greater the number of target lines, the greater the effect. It is shown in FIG. 17 when expressed by the reduction rate of the number of measurements. For example, when the maximum number of induction lines is 10, the number of measurements can be reduced by 80 to 90%. That is,
If the number of lines to be measured is 100 pairs, it is originally about 50
The measurement of 00 times only requires about 500 times.

In addition, except when measuring the true value of the near-end crosstalk attenuation amount, it is sufficient to arrange personnel only on the signal application side of the line (since there is no impedance termination on the other end side of the line, it is open). Since it is not necessary to allocate personnel, there is an advantage that it can be greatly reduced by extended operation.

However, FIGS. 16 and 17 show the case where the crosstalk characteristics of all the combinations made up of the lines to be measured are good.

[Brief description of drawings]

FIG. 1 is a block diagram showing a characteristic crosstalk measurement method adopted by the present invention.

FIG. 2 is a block diagram showing another characteristic crosstalk measurement method adopted by the present invention.

FIG. 3 shows the value measured by the conventional method shown in FIG. 18 as the true value on the horizontal axis and the value measured by the characteristic method according to the present invention shown in FIG. 1 on the vertical axis, and the standard value is shown. It is a graph used for determining.

FIG. 4 is a graph in which the value measured by the conventional method shown in FIG. 18 is taken as a true value on the horizontal axis and the value measured by another characteristic conventional method according to the present invention shown in FIG. 2 is taken as the vertical axis. 6 is a graph shown and used to determine a standard value.

FIG. 5 is a flowchart showing a part of a procedure of a method for measuring a crosstalk characteristic according to the present invention.

FIG. 6 is a flowchart showing the rest of the procedure of the method for measuring crosstalk characteristics according to the present invention.

FIG. 7 is a conceptual diagram showing the concept of a measuring apparatus for carrying out the method for measuring the crosstalk characteristic according to the present invention.

FIG. 8 is a flowchart showing a part of an operation procedure of the crosstalk characteristic measuring apparatus according to the present invention.

FIG. 9 is a flowchart showing a part of an operation procedure of the crosstalk characteristic measuring apparatus according to the present invention.

FIG. 10 is a flowchart showing a part of an operation procedure of the crosstalk characteristic measuring apparatus according to the present invention.

FIG. 11 is a flowchart showing a part of an operation procedure of the crosstalk characteristic measuring apparatus according to the present invention.

FIG. 12 is a block diagram showing a circuit configuration of a measuring apparatus for carrying out the crosstalk characteristic measuring method according to the present invention.

13 is an explanatory diagram showing a file structure of a memory 17 in FIG.

14 is an explanatory diagram showing a specific example of a file configuration of the memory 17 in FIG.

FIG. 15 is a measurement result of measuring 2234 sets of near-end crosstalk attenuation of a guided line having both ends opened by applying a signal of 1 kHz to 5 pairs of the induction lines having the other end opened in the measurement system of FIG. 1. It is a graph which shows.

FIG. 16 is a characteristic diagram showing the maximum number of induced lines dependent on the number of measurements with the number of target lines as a parameter when the present invention is implemented.

FIG. 17 is a characteristic diagram showing the maximum induction line number dependency in the number of measurements with the number of target lines as a parameter when the present invention is implemented, as a reduction rate of the number of measurements.

FIG. 18 is a block diagram showing a conventional crosstalk measurement method.

FIG. 19 is a flowchart showing a part of the procedure of the conventional crosstalk measurement method.

FIG. 20 is a flowchart showing the remaining part of the procedure of the conventional crosstalk measurement method.

FIG. 21 is a graph showing the relationship between the number of lines to be measured and the required number of measurements in the conventional crosstalk characteristic measurement.

[Explanation of symbols]

1 ... Oscillator, 2 ... Induction line, 4 ... Level meter, 5 ... Induced line, 11 ... Balanced pair communication cable, 12 ... Control part,
13 ... Signal distributor, 14 ... Scanner (changeover switch),
15 ... Frequency transmitter, 16 ... Selection level meter, 17 ...
Memory, 18 ... Standard value generating section for comparison, 19 ... Level comparator, 20 ... Display section, 21 ... Console section, 22
... printer, 23 ... terminal board conducting tool, M ... measuring device.

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Toshio Ono 1-1-6 Uchisaiwaicho, Chiyoda-ku, Tokyo Nihon Telegraph and Telephone Corporation

Claims (3)

[Claims] 1. When the number of lines to be measured is N (however, N is a plurality) out of the total number of lines constituting a balanced-pair communication cable, one line out of the N lines and another line 1
A method for measuring a crosstalk characteristic of a balanced-to-cable for detecting a combination of lines having a crosstalk attenuation amount with a line less than or equal to a certain specified value. Regarding lines, by connecting one end of these lines to a common signal source and leaving both ends of these lines in an open state, the specific plurality of lines are set as induction lines, and the specific line among the N lines is specified. For any one of the lines except the above multiple lines, a high-impedance level meter is connected to one end and the other end is opened to form a guided line, and the near end between the guided line and the guided line is set. Crosstalk attenuation,
A method for measuring a crosstalk characteristic of a balanced pair cable, comprising at least the step of measuring with a level meter. 2. When the number of lines to be measured is N (where N is a plurality) out of the total number of lines forming a balanced-pair communication cable, one line out of the N lines and another line 1
In a method for measuring a crosstalk characteristic of a balanced pair cable for detecting a combination of lines having a crosstalk attenuation amount with a line equal to or less than a certain specified value, (a) among the N lines to be measured, For specific multiple lines, one end of these lines is connected to a common signal source, and the other ends of these lines are opened so that the specific multiple lines become induction lines, and among the N lines With regard to any one line except the above-mentioned specific plural lines, a high impedance level meter is connected to one end of the line and the other end is opened to form a guided line, and between the induction line and the guided line. A first step of measuring the near-end crosstalk attenuation amount of the above with the level meter; and (b) a step of comparing the crosstalk attenuation amount measured in the first step with a predetermined first crosstalk attenuation amount standard value. Two And (c) as a result of the comparison, if the first crosstalk attenuation amount standard value is larger than the crosstalk attenuation amount measured in the first step, the combination of the induced line and the guided line in the first step Is stored as a problem, and (d) one of the specific plurality of lines that has become a guiding line in the first step is newly set as a guided line, and the rest is set as a new guiding line. A fourth step of executing the above first to third steps, and repeating the same until the number of inductive lines becomes one, and (e) after the fourth step is completed, Regarding the combination of the induced line and the induced line that was stored as a problem in step 3, when the induced line consists of multiple lines, each one is re-established as an induced line.
A fifth step of measuring the near-end crosstalk attenuation amount between the two lines with the guided line, which is a line, and (f) a predetermined crosstalk attenuation amount measured in the fifth step. A sixth step of comparing with a second crosstalk attenuation amount standard value; and (g) if the second crosstalk attenuation amount standard value is larger than the crosstalk attenuation amount measured in the fifth step. The seventh step of storing the combination of the guiding line and the guided line in the step as a problem; and (h) the combination of the guiding line and the guided line stored as a problem in the seventh step becomes a guiding line. A signal source is connected to one end of one line, the other end is terminated with a predetermined terminating resistor, a level meter is connected to one end of the one line to be the guided line, and the other end is terminated with a predetermined terminating resistor. Near-end crosstalk between both lines An eighth step of measuring an attenuation amount with the level meter; and (a) a ninth step of comparing the crosstalk attenuation amount measured in the eighth step with a predetermined third crosstalk attenuation amount standard value, (10) If the third crosstalk attenuation amount standard value is larger than the crosstalk attenuation amount measured in the eighth step, the tenth step of storing the combination of the induction line and the guided line in the eighth step as a defect. A method for measuring the crosstalk characteristic of a balanced pair cable, comprising: 3. When the number of lines to be measured is N (where N is a plurality) out of the total number of lines forming a balanced-pair communication cable, one line out of the N lines and another line 1
A device for measuring the crosstalk characteristics of a balanced pair cable for detecting a combination of lines whose crosstalk attenuation with the line is less than a specified value, a signal source that generates a signal of a predetermined frequency, and a level meter. Of the N lines, a control unit for selecting and designating a line which is an open line to be a guide line and a line which is open line to be a guided line according to a predetermined rule, and a line which is designated as a guide line by the control unit. Switch means for connecting the signal source to the other end and connecting the level meter to the other end of the line designated as the guided line, and the measured value by the level meter as a given crosstalk attenuation standard value. A device for measuring the crosstalk characteristic of a balanced pair cable, comprising: comparison means for comparing, and storage means for storing a combination of an induction line and an induced line determined to have a problem from the comparison result. .