JPH10293084A - Connection testing method for optical fiber cable - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for testing connection of an optical fiber cable where in an accurate connection loss value is obtained by measuring from one side. SOLUTION: The first and second optical fiber cables 1 and 2 are connected, and a loop back is formed by connecting an optical fiber at a terminal. To the first core 11 of the first optical fiber cable 1, an OTDR (optical track tester) 3 is connected for forward-direction measurement. To the second core 12 of the first optical fiber cable 1, the OTDR 3 is connected for reverse-direction measurement. A set refractive index of the OTDR 3 is so changed that the connection loss obtained from the two measurements are equal each other, for obtaining a reference refractive index N. Based on the refractive index N, a connection loss is measured.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a method for measuring a connection loss when a plurality of optical fiber cables having different optical characteristics are connected.

[0002]

2. Description of the Related Art The quality of a connection point and the connection loss when an optical fiber cable is connected are measured by a backscattered light method. In this method, when a strong light pulse is incident on an optical fiber, the light pulse is attenuated by scattering and absorption as it propagates through the optical fiber, but of the scattered light, the light scattered backward is reduced. This is a method of observing on the incident side and calculating based on the numerical value.

That is, since the scattering ratio is constant in the length direction of the fiber, the intensity of the scattered light is proportional to the intensity of the propagating light at that location. Therefore, if the intensity of the scattered light is measured, the loss at that location can be measured. By the way, the scattered light from a point far from the point near the incident end takes a longer propagation time, so the delay time corresponds to the distance of the optical fiber. Therefore, by observing the level of the backscattered light with an oscilloscope, the loss of each part including the connection point of the optical fiber can be measured.

In order to accurately measure the connection loss between optical fibers having different backscattering coefficients and relative refractive indices, an optical pulse test is performed from the upper side and the lower side of an optical fiber cable, and each measured value is averaged. (Details described later).

[0005]

Since it is troublesome to perform the optical pulse test from the upper side and the lower side of the above-mentioned optical fiber cable, that is, at both ends, it has hardly been actually performed.

Therefore, when the monitor waveform has a rising edge, waveform comparison between a plurality of connection points is performed, and a case where a waveform that is peculiar to other waveforms is determined to be a connection failure.

Therefore, a connection failure can be determined, but a connection loss value cannot be determined. An object of the present invention is to provide a connection test method for an optical fiber cable capable of obtaining a connection loss value by measurement from one side.

[0008]

In order to achieve the above object, as a first method, a first optical fiber cable and a second optical fiber cable are connected. At this time, the first core of the first optical fiber cable is connected to the first core of the second optical fiber cable, and the connection part is S _1.
And Similarly, connecting the second core of the first optical fiber cable and the second core of the second optical fiber cable,
And the connecting portion S _2. At the final end, the first fiber of the second optical fiber cable is connected to the second fiber of the second optical fiber cable. In the above connection state, the tester OT is provided at the first center of the first optical fiber cable.
Connect the DR and measure in the forward direction. At this time, connection losses ΔS ₁ and ΔS ₂ are measured. In the connection state described above, the tester OTDR is connected to the second core of the first optical fiber cable, and measurement in the reverse direction is performed. At this time, connection losses ΔS ′ ₁ and ΔS ′ ₂ are measured.

According to the above measurement procedure, the connection loss of S ₁ is the average value of ΔS ₁ and ΔS ′ ₁ , and the connection loss of S ₂ is Δ
The gist is to obtain the average value of S ₂ and ΔS ′ ₂ .

As a second method means, in the first method means, (ΔS ₁ + ΔS ′ ₁ ) / 2 = (ΔS ₂ + Δ
The gist of the present invention is to change the refractive index input of the OTDR so as to obtain S ′ ₂ ) / 2 and measure the connection loss based on the refractive index input when the above formulas match.

[0011]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a connection test method for an optical fiber cable according to the present invention.

First, the measurement principle (bidirectional averaging) according to the present invention will be described. When light is incident on the optical fiber, the measured waveform step at the connection point appears upward, downward, or appears without a step. This step is not the splice loss itself, but a step in which the level difference between the backscattered light of the two optical fiber cables and the true splice loss are combined.

For example, as shown in FIG. 1 and No. When No. 2 is connected, the backscattering coefficient is No. 2. 1 <No. At 2, the measured waveform from the upper side appears as shown in FIG. 4A, and the measured waveform from the lower side appears as shown in FIG.

No. 1 and No. Assuming that the backscattered light level difference of the two cables is a and the connection loss is S, a waveform of (a-S) appears when measured from the upper side, and a waveform of (a + S) appears when measured from the lower side. .

Therefore, when the connection loss is obtained by utilizing this relationship, S = a− (a−S) (1) from FIG. 4A and S = (a + S) −a from FIG. (2) If the equation (1) + (2) is obtained,

## EQU1 ## 2S = {a- (a-S)} + {(a + S) -a} = (a + S)-(a-S) (3) The waveform of the first term in equation (3) is reduced. If the sign is positive,
The second term is when the waveform rises, and the sign becomes negative. Therefore, to obtain the connection loss S from the equation (3), S = {(a + S) − (a−S)} 2 (4)

That is, an average value is obtained by measuring from both ends.

Next, an embodiment of the present invention will be described.

FIG. 1 is a block diagram for explaining the present embodiment. In the figure, a first optical fiber cable 1 and a second optical fiber cable 2 are each formed of n optical fibers. The two optical fiber cables 1 and 2, the connection point S _1, S _2, ... corresponding optical fiber comrades each other in the S _n are fusion spliced by using a fusing device (not shown).

The test method of the present invention is performed according to the following procedure.

[0020] The first fiber 11 of the first optical fiber cable 1 and the first fiber 21 of the second optical fiber cable 2 are connected. The connection portion is S _1.

Similarly, the second core 12 of the first optical fiber cable 1 and the second core 2 of the second optical fiber cable 2
2 is connected. The connection portion and S _2.

[0022] At the final end, the first fiber 21 and the second fiber 22 of the second optical fiber cable 2 are connected.
This connection may be a connector connection. This connection is designated as _S0 . Thus, a loopback is formed.

[0023] First, measurement is performed in the forward direction (the waveform measurement from the upper side described above) of the first centers 11 and 21.

As shown in FIG. 1A, an OTDR (optica) is provided at the first fiber 11 of the first optical fiber cable 1.
l time domain reflectometry
er) 3) to perform forward measurement. This measurement is performed in the opposite direction in the second centers 12 and 22.

At this time, connection loss ΔS ₁ (at S ₂ ), Δ
S ₂ (at S ₂ ) is measured.

FIG. 2A shows the observed waveform at that time.

[0027] Next, measurement is performed in the opposite direction of the first centers 11 and 21 (waveform measurement from the lower side described above).

As shown in FIG. 1B, the OTDR 3 is connected to the second fiber 12 of the first optical fiber cable 1,
Measure in the opposite direction. In the case of this measurement,
In cases 2 and 22, the measurement is performed in the forward direction.

At this time, connection loss ΔS ′ ₁ (at S ₁ ),
ΔS ′ ₂ (at S ₂ ) is measured. The observed waveform at this time is shown in FIG.

[0030] As described above, according to the measurement principle described above, the connection loss of S ₁ is (ΔS ₁ −ΔS ′ ₁ ) / ₂ , and the connection loss of S ₂ is (ΔS ₂ −ΔS ′ ₂ ) / 2.

However, on the OTDR, ΔS ′ ₁ and ΔS ′ ₁
S 'if ₂ is put numerical because it is negative _{value, (ΔS 1 + ΔS' 1} ) / 2 and (ΔS ₂ + ΔS _'2)
/ 2. . Here, the following assumptions are made.

The connection losses at S ₁ and S ₂ are equal.

If the connection is good, any connection point can be regarded as having the same connection loss, but for the time being, two points considered to be accurate are selected as reference connection points.

Then, (ΔS ₁ + ΔS ′ ₁ ) / 2 = (ΔS ₂ + ΔS ′ ₂ ) / 2 should be obtained.

However, the actual measured values are different.

This is because the position of the Fresnel reflection on the screen obtained from the reflection time differs from the actual distance because the setting of the refractive index of the OTDR is different.

[0037] Then, by changing the refractive index input of the OTDR, (ΔS ₁ + ΔS ′ ₁ ) / 2 = (ΔS ₂ + Δ
S ′ ₂ ) / 2.

[0038] The refractive index at this time becomes an appropriate value used at the time of measurement, and in the subsequent measurement of connection loss, a value obtained at a position based on the refractive index N is used as connection loss.

[0039]

As described above, according to the optical fiber cable connection test method of the present invention, the connection loss between optical fiber cables having different back scattering coefficients and relative refractive indices can be accurately measured by measurement from one side. it can.

Therefore, there is no need to arrange personnel on both sides, and the measurement time can be reduced.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a connection test method for an optical fiber cable according to the present invention.

FIG. 2 is an explanatory diagram of an observed waveform in the connection test method of FIG.

FIG. 3 is a diagram for explaining a measurement principle according to the present invention and is a diagram showing a state where optical fiber cables having different backscattering coefficients are connected.

FIG. 4 shows a state in which the optical fiber cable shown in FIG. 3 is connected.
(A) is a measured waveform diagram from the upper side, and (B) is a measured waveform diagram from the lower side.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 1st optical fiber cable 2 2nd optical fiber cable 3 OTDR (optical line tester) 11 1st core of 1st optical fiber cable 12 2nd core of 1st optical fiber cable 21 2nd optical fiber First core of cable 22 Second core of second optical fiber cable

Claims (2)

[Claims] 1. A first optical fiber cable is connected to a second optical fiber cable. At this time, the first heart-th of the first optical fiber cable to connect the first heart-th of the second optical fiber cable, the connection portion is S _1. Similarly,
A second heart-th of the first optical fiber cable, and a second heart-th of the second optical fiber cable connected to the connection portion S _2. At the final end, the first of the second fiber optic cable
The core is connected to the second core of the second optical fiber cable. In the connection state described above, the tester OTDR is connected to the first fiber of the first optical fiber cable to perform forward measurement. At this time, connection losses ΔS ₁ and ΔS ₂ are measured. In the connection state described above, the tester OTDR is connected to the second core of the first optical fiber cable, and measurement in the reverse direction is performed. At this time, connection losses ΔS ′ ₁ and ΔS ′ ₂ are measured. As described above, the connection loss of S ₁ is obtained as an average value of ΔS ₁ and ΔS ′ ₁ , and the connection loss of S ₂ is obtained as an average value of ΔS ₂ and ΔS ′ ₂ . A connection test method for an optical fiber cable, wherein the measurement is performed according to the above procedures. 2. The connection test method according to claim 1, wherein
(ΔS ₁ + ΔS ′ ₁ ) / 2 = (ΔS ₂ + ΔS ′ ₂ ) / 2
The refractive index input of the tester OTDR is changed so that
A connection test method for an optical fiber cable, wherein a connection loss is measured based on a refractive index input when the above expressions match.