JPH10160635A - Skew inspection method of multifiber optical fiber tape and skew measurement device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To inspect the skew of a multifiber optical fiber easily and surely by branching pulse beams into the same number as the number of fibers of a multifiber tape and applying each branched, pulse beam to each fiber of the multifiber tape. SOLUTION: Pulse beams from a light source 11 are branched into the same number as the number of fibers of an optical fiber tape 15 (multifiber optical tape) by an optical star coupler 13a, and are allowed to enter each fiber of the optical fiber tape 15 via a light connector conversion adapter 16a. Each light pulse propagated through each core of the tape fiber 15 is synthesized by an optical star coupler 13b via a light connector conversion adapter 16b at the other edge, and is allowed to enter a light-sampling oscilloscope 12. In a waveform observed by the oscilloscope 12, pulse beams through each core of the tape fiber 15 are superposed. By measuring the spread of the superposed pulse beams, it can be inspected whether the skew of the tape fiber 15 is within a tolerance without measuring a propagation time difference for each optical fiber of the tape 15.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a skew inspection method and a skew inspection apparatus for a multi-core optical fiber for checking the skew of a multi-core optical fiber used in a parallel optical transmission system. Here, the skew of a multi-core optical fiber is
The variation in the light propagation time of each optical fiber constituting the multi-core optical fiber. In a multi-core optical fiber, even though the lengths of the optical fibers are uniform, variations in the refractive index distribution and the like cause variations in the optical path length, resulting in variations in light propagation time and skew. Is generated.

[0002]

2. Description of the Related Art In a parallel optical transmission system for realizing high-throughput data transmission at low cost, a multi-core optical fiber, particularly a tape fiber in which a plurality of optical fibers are bundled in a tape form, is often used as a transmission medium. In this parallel optical transmission system, skew (variation in signal propagation time between transmission paths) is one of the factors that limit its performance. Among the skews of the parallel optical transmission system, the skew of the multi-core optical fiber is a major factor. Therefore, in the manufacturing process of the multi-core optical fiber,
It is necessary to check whether the skew exceeds a design allowable range and sort the skew.

As a method of checking the skew of a multi-core optical fiber, there is a method of actually measuring the skew. It measures the light propagation time of each core of a multi-core optical fiber and finds the difference between its maximum and minimum values. Fig. 6 shows the configuration of a conventional multi-fiber optical fiber skew measurement device (Reference: Motoi Abe, Atsushi Takai, "Evaluation of Skew Accuracy of Tape Fiber", 1992 IEICE Spring Conference B-921).
.

In FIG. 1, a pulse light emitted from a pulse light source 11 is split into two by an optical coupler 18. One pulse light is incident on one core of the tape fiber 15 via an optical connector conversion adapter 16 for converting between a single-core optical connector and a multi-core optical connector, and the other pulse light is incident on a reference optical fiber 19. You. Each pulsed light propagates through the input fiber, is reflected at the open end of each fiber, propagates through each fiber again, is multiplexed by the optical coupler 18, and is incident on the optical sampling oscilloscope 12. The timing generator 14 gives a reference timing to the pulse light source 11 and the optical sampling oscilloscope 12.

[0005] One waveform observed by the optical sampling oscilloscope 12 is a pulse light reciprocating in one core of the tape fiber 15, and the other waveform is a pulse light reciprocating in the reference optical fiber 19. By observing the two pulse lights, the propagation time difference of one core of the tape fiber 15 with respect to the reference optical fiber 19 is measured.
By performing this operation for each core of the tape fiber 15, the relative distribution of the light propagation time of each channel of the measurement system can be obtained.

Further, at the measurement reference point A, the tape fiber 1
5 and the reference optical fiber 19 are removed in the same manner, and the previously measured data is calibrated using the measured data. As a result, the propagation time difference caused by the optical path length difference other than the tape fiber 15 for each channel is removed, and the relative distribution of the light propagation time for the round trip of each core of the tape fiber 15 is obtained. One half of the difference between the maximum value and the minimum value is the skew of the tape fiber 15.

[0007]

However, the skew inspection method of measuring the light propagation time of each fiber of the multi-core optical fiber one by one as described above is a very complicated operation. In particular, when the number of channels, that is, the number of cores of a multi-core optical fiber is increased to improve transmission throughput,
It becomes an increasingly cumbersome task.

[0008] Further, consuming a large amount of labor for checking the skew of a multi-core optical fiber also increases the manufacturing cost of a parallel optical transmission system using the same. An object of the present invention is to provide a skew inspection method and a skew inspection device for a multi-core optical fiber, which can easily and surely inspect the skew of the multi-core optical fiber.

[0009]

A skew inspection method and a skew inspection apparatus for a multi-core optical fiber according to the present invention branch one pulse light at least as many as the number of cores of the multi-core optical fiber to be inspected. Each pulsed light is incident on each core of the multi-core optical fiber from one end thereof and propagated, and each pulsed light emitted from the other end of each core is multiplexed, and each pulsed light according to the spread of the waveform is combined. Observe the transit time difference. This makes it possible to easily and reliably inspect whether or not the skew of the multi-core optical fiber is within a predetermined allowable range.

Further, the skew inspection method and the skew inspection apparatus for a multi-core optical fiber according to the present invention are arranged such that one pulse light is branched into at least the same number as the number of cores of the multi-core optical fiber to be inspected. Is input to each core of the multi-core optical fiber from one end thereof and propagated, and each pulse light reflected and returned at the other end of each core is multiplexed, and propagation of each pulse light according to the spread of the waveform is performed. Observe the time difference. This allows
Whether or not the skew of the multi-core optical fiber is within a predetermined allowable range can be easily and reliably checked.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION

FIG. 1 shows a first embodiment of the present invention. In the figure, the pulse light emitted from the pulse light source 11 is branched into the same number as the number of cores of the tape fiber 15 by the optical star coupler 13a, and is incident on each core of the tape fiber 15 via the optical connector conversion adapter 16a. . Each pulse light propagated through each core of the tape fiber 15 is supplied to the optical connector conversion adapter 16b at the other end.
Are input to the optical star coupler 13b, multiplexed, and input to the optical sampling oscilloscope 12. The timing generator 14 gives a reference timing to the pulse light source 11 and the optical sampling oscilloscope 12.

The waveform observed by the optical sampling oscilloscope 12 is a waveform in which the pulse light propagating through each core of the tape fiber 15 is superimposed. By measuring the spread of the superimposed pulse light, the tape fiber 15
It is possible to reliably check whether the skew of the tape fiber 15 is within a predetermined allowable range without measuring the propagation time difference for each core.

In this embodiment, the optical star coupler 1
3a, 13b, optical connector conversion adapters 16a, 13b
In the state where the tape fibers 15 are detached and connected at the measurement reference points A and B, there is almost no difference in the optical path length between the channels or the difference can be neglected as a whole. Further, the optical star coupler 13a and the optical connector conversion adapter 16a, or the optical connector conversion adapter 16b and the optical star coupler 13b can be configured using an optical waveguide circuit or the like.

Instead of using the optical sampling oscilloscope 12, a high-speed optical / electrical conversion unit and an electric oscilloscope or other units may be used for the observation of the pulse light waveform and the measurement of the propagation time difference. (Second Embodiment: Claims 2 and 3) FIG. 2 shows a second embodiment of the present invention.

In FIG. 1, a pulse light emitted from a pulse light source 11 is applied to a tape fiber 1 by an optical star coupler 13.
The optical connector conversion adapter 1 is branched into the same number as the number of cores 5
The light is incident on each of the cores of the tape fiber 15 through the respective optical fibers 6. Each pulse light that has propagated through each core of the tape fiber 15 is reflected at the open end of the tape fiber 15, propagates through each core again, is multiplexed by the optical star coupler 13, and enters the optical sampling oscilloscope 12. The timing generator 14 gives a reference timing to the pulse light source 11 and the optical sampling oscilloscope 12.

The waveform observed by the optical sampling oscilloscope 12 is a waveform in which pulse light reciprocating in each center of the tape fiber 15 is superimposed. By measuring the spread of the superimposed pulse light, the tape fiber 15
It is possible to reliably check whether the skew of the tape fiber 15 is within a predetermined allowable range without measuring the propagation time difference for each core. However, in the present embodiment, the spread of the pulse light observed by the optical sampling oscilloscope 12 is twice as large as that in the first embodiment.

In this embodiment, the optical star coupler 1
3 and the optical connector conversion adapter 16 are connected to the measurement reference point A
In the state where the tape fiber 15 is removed in step (1), an optical path length difference between the channels is almost negligible or can be ignored as a whole. In addition, the optical star coupler 13
The optical connector conversion adapter 16 can also be configured using an optical waveguide circuit or the like.

The end of the tape fiber 15 may be in a state in which an optical connector is mounted, or may be in a state in which the end is simply cut to remove the coating. An optical sampling oscilloscope 1 is used for observing the pulse light waveform and measuring the propagation time difference.
Instead of using 2, a high-speed optical / electrical conversion means and an electric oscilloscope or other means may be used.

(Third Embodiment) FIG. 3 shows a third embodiment of the present invention.
An embodiment will be described. In the figure, a pulse light source 11, an optical sampling oscilloscope 12, an optical star coupler 13
a, 13b, the timing generator 14, the tape fiber 15, and the optical connector conversion adapters 16a, 16b
This is the same as that of the first embodiment shown in FIG. However, the feature of the present embodiment that the tape fiber 15 has n cores (n = 5 in the figure) is that the optical fiber length adjusting means 17-
1 to 17-n are inserted. The optical path length adjusting means 17-1 to 17-n are set so as to eliminate the optical path length difference between the respective channels when the tape fibers 15 are detached and connected at the measurement reference points A and B. The function of checking whether or not the skew of the tape fiber 15 is within a predetermined allowable range is the same as in the first embodiment.

In this embodiment, the optical path length adjusting means 17 includes the optical star coupler 13a and the optical connector conversion adapter 1.
6a, but may be inserted between the optical connector conversion adapter 16b and the optical star coupler 13b. The optical path length adjusting means 1 is provided both between the optical star coupler 13a and the optical connector conversion adapter 16a and between the optical connector conversion adapter 16b and the optical star coupler 13b.
7 may be inserted.

(Fourth Embodiment) FIG. 4 shows a fourth embodiment of the present invention.
An embodiment will be described. In the figure, a pulse light source 11, an optical sampling oscilloscope 12, an optical star coupler 13,
The timing generator 14, the tape fiber 15, and the optical connector conversion adapter 16 are the same as those of the second embodiment shown in FIG. However, the tape fiber 15 has n cores (n = 5 in the figure).

The feature of this embodiment is that the optical star coupler 13
The optical path length adjusting means 17-1 to 17-n are inserted between the optical connector conversion adapter 16 and the optical connector conversion adapter 16. The optical path length adjusting means 17-1 to 17-n are set so as to eliminate the optical path length difference between the respective channels when the tape fiber 15 is removed at the measurement reference point A. The function of checking whether or not the skew of the tape fiber 15 is within a predetermined allowable range is the same as in the second embodiment.

(Embodiment of Optical Path Length Adjusting Means 17) FIG.
Shows an embodiment of the optical path length adjusting means 17. (a) uses an optical fiber 21 of an appropriate length. When changing the optical path length, replace with an optical fiber having a different length. (b) is one in which collimating lenses 23a and 23b are arranged between opposing optical fibers 22a and 22b. When changing the optical path length, the collimating lens 23 is used.
Change the distance between a and 23b.

(C) shows an optical waveguide circuit 24 having a predetermined optical path length disposed between optical fibers 22a and 22b. Further, as the optical waveguide circuit 24, a plurality of waveguides having different optical path lengths and optical fibers 22a and 22b
A combination of an optical switch for switching the connection between the optical waveguide and each waveguide may be used.

[0025]

As described above, in the skew inspection method and the skew inspection apparatus for a multi-core optical fiber according to the present invention, whether or not the skew of the multi-core optical fiber is within a predetermined allowable range is surely inspected. be able to.

[Brief description of the drawings]

FIG. 1 is a diagram showing a first embodiment of the present invention.

FIG. 2 is a diagram showing a second embodiment of the present invention.

FIG. 3 is a diagram showing a third embodiment of the present invention.

FIG. 4 is a diagram showing a fourth embodiment of the present invention.

FIG. 5 is a diagram showing an embodiment of an optical path length adjusting means 17;

FIG. 6 is a diagram showing a configuration of a conventional multi-core optical fiber skew measuring device.

[Explanation of symbols]

 Reference Signs List 11 pulse light source 12 optical sampling oscilloscope 13 optical star coupler 14 timing generator 15 tape fiber 16 optical connector conversion adapter 17 optical path length adjusting means 18 optical coupler 19 reference optical fiber 21, 22 optical fiber 23 collimating lens 24 optical waveguide circuit

Claims (3)

[Claims] 1. A single pulse light is branched into at least the same number as the number of cores of a multi-core optical fiber to be inspected, and each of the branched pulse lights is made incident on one end of the multi-core optical fiber from one end thereof and propagated. The pulse light emitted from the other end of each core is multiplexed, and it is determined whether the skew of the multi-core optical fiber is within a predetermined allowable range from the propagation time difference of each pulse light according to the spread of the waveform. A skew inspection method for a multi-core optical fiber, characterized by inspecting. 2. One pulse light is branched into at least the same number as the number of optical fibers of a multi-core optical fiber to be inspected, and each of the branched pulse lights is made incident on one end of the multi-core optical fiber from one end thereof and propagated. The pulse light reflected at the other end of each core is returned and combined, and the skew of the multi-core optical fiber is within a predetermined allowable range based on the propagation time difference of each pulse light according to the spread of the waveform. A skew inspection method for a multi-core optical fiber, wherein the skew inspection is performed. 3. A pulse light source that emits pulsed light having a predetermined pulse width, a branching unit that branches the pulsed light into at least the same number as the number of cores of a multi-core optical fiber to be inspected, and enters each of the cores; Multiplexing means for multiplexing the pulsed light propagating through each core of the multi-core optical fiber; observing a waveform multiplexed by the multiplexing means; An optical waveform inspection means for inspecting whether or not the skew of the optical fiber is within a predetermined allowable range.