JP2000131187A - Device for measuring eccentricity of optical fiber connector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide the eccentricity-measuring device of an optical connector for easily measuring the eccentricity of the core part of an optical fiber being inserted into the fiber hole and for reducing the measurement time. SOLUTION: A device is provided with a light transmission stage 101 that is formed by glass or the like, a positioning tool 102 that is fixed on the stage 101, a light source 103 for projecting light from the lower portion of the stage 101, a CCD camera 104 that is an image pick-up means being arranged at the upper portion of the stage 101, and an arithmetic unit 105 for calculating the amount of eccentricity of an optical connector. The center position of a fiber hole 111 is calculated based on the image information on transmission illumination light from the fiber hole 111 whose image is picked up by the CCD camera 104 and the position information on the stage 101 that is detected by a laser length-measuring device 108 is calculated by the arithmetic unit 105. Then, the amount of eccentricity of the fiber hole 111 is calculated based on the center position of the positioning hole 114 obtained in advance and that of the fiber hole 111.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for measuring the eccentricity of an optical fiber connector (hereinafter referred to as an optical connector) used when connecting an optical fiber. For more information,
The present invention relates to an eccentricity measuring device for an optical connector that measures the eccentricity of a fiber hole formed in an optical connector or the eccentricity of a core portion of an optical fiber inserted into the fiber hole.

[0002]

2. Description of the Related Art As a general optical connector, an optical connector C called an MT connector as shown in FIG. 7 is known. The optical connector C is composed of a member called a ferrule 1 attached to an end of the optical fiber 2. The ferrule 1 is formed with a set of guide pin holes 12 for inserting the guide pins 3 made of stainless steel at the connection end face 11 with the optical connector C on the other side. Joint end face 11
A fiber hole 13 for arranging the optical fibers 2 is formed between the guide pin holes 12. Two optical connectors C
Are positioned with respect to each other using the guide pin holes 12 and the guide pins 3 and are butt-connected. This connection state is held by a clamp spring (not shown).

In the optical connector C as described above,
It is necessary to minimize connection loss due to connection with the optical connector C on the other side. The connection loss is substantially determined by the shift amount of the center position between the optical fibers 2 facing each other when the optical connector C is connected. For this reason, in order to minimize the displacement, the fiber hole 13 or the fiber hole 13 is determined based on the position of the guide pin hole 12 formed in the optical connector C.
Measuring the eccentricity of the core of the optical fiber 2 inserted into the
It is necessary to use an optical connector having an eccentricity satisfying a predetermined standard as the optical connector C.

As an apparatus for measuring the amount of eccentricity of the fiber hole 13, an apparatus as shown in FIG. 8 has been proposed.
In this apparatus, the ferrule 1 is fixed to a stage 21 movable in a horizontal plane, and a light source 22 is provided below the stage 21. Then, illumination light is incident from one end of the guide pin hole 12 and the fiber hole 13, and transmitted illumination light from the guide pin hole 12 and the fiber hole 13 is sequentially imaged by the CCD camera 23 while moving the stage 21. . Each hole 1 obtained from the captured image of the transmitted illumination light
The center positions of the holes 12 and 13 are detected based on the edge positions 2 and 13 and the movement position of the stage 21, and from these center positions, the center of the fiber hole 13 with reference to the center position of the guide pin hole 12. The calculation unit 24 calculates the eccentricity of the position.
Is calculated and measured by. Reference numeral 25 denotes a TV monitor for displaying an image captured by a CCD camera.

As an apparatus for measuring the eccentricity of the core of an optical fiber, the following apparatus has been proposed. Into the guide pin hole, insert a sleeve formed with the same diameter as the guide pin hole diameter and having a single-core optical fiber attached to the center, and from one end of each of the optical fiber and the single-core optical fiber fixed to the optical connector. Illumination light is incident, and transmitted illumination light from each optical fiber is imaged. Detecting the center position of the core of each optical fiber obtained from the captured transmitted illumination light image, and measuring the eccentricity of the center position of the core with reference to the center position of the guide pin hole from these center positions are doing. (See Japanese Patent No. 2518967)

[0006]

However, in the above-described measuring apparatus, the illumination light is incident on all of the guide pin holes 12 and the fiber holes 13 or the core, and the transmitted illumination light is imaged. Since the processing is performed to detect the center position, the time required to complete the measurement of the eccentricity becomes long. In the above-described apparatus for measuring the eccentricity of the core portion of the optical fiber, the sleeve attached so that the core portion of the single-core optical fiber is located at the center position in order to detect the center position of the guide pin hole 12. It is necessary to prepare special parts. If the core portion is not located at the center position of the sleeve, as described in the above-mentioned publication, it is necessary to devise a measuring method such as rotating the sleeve and performing a plurality of measurements, which complicates the measurement, The measurement time becomes longer.

SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and can measure the eccentricity of a fiber hole or a core portion of an optical fiber inserted into the fiber hole easily, and can reduce the time required for the measurement. It is an object to provide a measuring device.

[0008]

According to the first aspect of the present invention, in an optical fiber connector having a guide pin hole and a fiber hole, the eccentricity of the position of the fiber hole with respect to the position of the guide pin hole is determined. An eccentricity measuring device for an optical fiber connector to be measured, wherein a set of positioning holes having the same inner diameter and spacing as a set of guide pin holes formed in a master optical connector are formed and inserted into the positioning holes. An optical fiber connector fixing member for fixing the optical fiber connector by inserting the set guide pin into the guide pin hole of the optical fiber connector, and illumination light incidence means for entering illumination light into the fiber hole on one side of the fiber hole When,
On the other side of the fiber hole, imaging means for imaging the transmitted illumination light from the fiber hole of the optical fiber connector fixed to the optical fiber connector fixing member, and based on the transmitted illumination light from the fiber hole imaged by the imaging means. Fiber hole position detecting means for detecting the center position of the fiber hole,
Based on the center position of the positioning hole of the optical fiber connector fixing member prepared in advance and the center position of the fiber hole detected by the fiber hole position detecting means, the fiber hole of the fiber hole based on the position of the guide pin hole is used. Eccentricity measuring means for measuring the eccentricity at the center position.

According to the eccentricity measuring device for an optical fiber connector according to the first aspect, the illumination light is incident on the guide pin hole, the transmitted illumination light is imaged, and the center position is determined based on the imaged image. There is no need to detect, and the time for measuring the eccentricity of the center position of the fiber hole with reference to the position of the guide pin hole is reduced. In addition, since the measurement can be started by fixing the optical connector to the optical fiber connector fixing member, the measurement of the eccentric amount becomes easy.

According to a second aspect of the present invention, in the first aspect of the present invention, there is provided a table to which an optical fiber connector fixing member is fixed and supported movably in a predetermined plane;
While having a table driving means for moving the table and a table position detecting means for detecting the table position in a predetermined plane, the fiber hole position detecting means determines the edge position of the image of the transmitted illumination light imaged by the imaging means. In addition to the detection, the center position of the fiber hole is detected based on the edge position and the table position detected by the table position detecting means. In this case,
The fiber hole position detection means detects the edge position of the image of the transmitted illumination light imaged by the imaging means, and determines the center position of the fiber hole based on the edge position and the table position detected by the table position detection means. Since the detection can be performed, the center position of the fiber hole can be detected more accurately.

According to a third aspect of the present invention, in the first aspect of the present invention, the illumination light enters the positioning hole on one side of the positioning hole by the illumination light incident means, and the other side of the positioning hole is detected by the imaging means. The side picks up the transmitted illumination light from the positioning hole, and detects the center position of the positioning hole based on the transmitted illumination light picked up by the image pickup means. Storage means for storing the center position of the positioning hole, the eccentricity measurement means reads the center position of the positioning hole stored in the storage means, and the readout center position of the positioning hole and the fiber hole position detection means The eccentricity of the center position of the fiber hole with reference to the position of the guide pin hole is measured based on the detected center position of the fiber hole. In this case, even when the eccentricity of a plurality of optical connectors is continuously measured, the measurement is performed by reading the center position of the positioning hole stored in the storage means when measuring the eccentricity of the fiber hole. Because it can be done continuously,
It is possible to easily and continuously measure the eccentricity of the fiber hole.

According to a fourth aspect of the present invention, a guide pin hole and a fiber hole are formed, and the position of the guide pin hole in the optical fiber connector in which the optical fiber is inserted and fixed in the fiber hole is used as a reference. Eccentricity measuring device for an optical fiber connector for measuring the eccentricity of the position of a core portion of an optical fiber, comprising: a set of guide pin holes formed in a master optical connector having the same inner diameter and spacing as a set of guide pin holes. A positioning hole is formed, an optical fiber connector fixing member for fixing the optical fiber connector by inserting the guide pin hole of the optical fiber connector into the guide pin inserted in the positioning hole, and one end side fixed to the optical fiber connector At the other end of the optical fiber, an illumination light input means for inputting illumination light to the optical fiber, and an optical fiber having a fiber hole formed therein. On the end face side of the fiber connector, based on the imaging means for imaging the transmitted illumination light from the core of the optical fiber fixed to the optical fiber connector fixing member, based on the transmitted illumination light from the core imaged by the imaging means. A core position detecting means for detecting the center position of the core, a center position of a positioning hole of the optical fiber connector fixing member prepared in advance, and a center position of the core detected by the core position detecting means. And an eccentricity measuring means for measuring the eccentricity of the center position of the core with reference to the position of the guide pin hole based on the eccentricity.

According to the eccentricity measuring device for an optical fiber connector according to the fourth aspect, the illumination light is incident on the guide pin hole, the transmitted illumination light is imaged, and the center position is determined based on the imaged image. Since there is no need to detect the eccentricity, the time for measuring the eccentricity of the center position of the core with reference to the position of the guide pin hole is reduced. In addition, since the measurement can be started by fixing the optical connector to the optical fiber connector fixing member, the measurement of the eccentric amount becomes easy.

According to a fifth aspect of the present invention, in accordance with the fourth aspect of the present invention, there is provided a table to which an optical fiber connector fixing member is fixed and is movably supported in a predetermined plane.
While having a table driving means for moving the table and a table position detecting means for detecting a table position in a predetermined plane, the core position detecting means determines an edge position of an image of the transmitted illumination light imaged by the imaging means. In addition to the detection, the center position of the core portion is detected based on the edge position and the table position detected by the table position detecting means. In this case, the core position detecting means detects the edge position of the image of the transmitted illumination light imaged by the imaging means, and detects the core position based on the edge position and the table position detected by the table position detecting means. Since the center position of the core can be detected, the center position of the core can be detected more accurately.

According to a sixth aspect of the present invention, in the fourth aspect of the present invention, the illumination light enters the positioning hole on one side of the positioning hole by the illumination light incident means, and the other side of the positioning hole is detected by the imaging means. The side picks up the transmitted illumination light from the positioning hole, and detects the center position of the positioning hole based on the transmitted illumination light picked up by the image pickup means. Storage means for storing the center position of the positioning hole, the eccentricity measuring means reads the center position of the positioning hole stored in the storage means, and the read center position of the positioning hole and the core position detection means The eccentricity of the center position of the core with reference to the guide pin hole position is measured based on the detected center position of the core. In this case, even when the eccentricity of the plurality of optical connectors is continuously measured, the measurement is performed by reading the center position of the positioning hole stored in the storage means when measuring the eccentricity of the core. Since the measurement can be performed continuously, the amount of eccentricity of the core portion can be easily and continuously measured.

The invention described in claim 7 is the third or sixth invention.
In the invention described in (1), a table to which an optical fiber connector fixing member is fixed and movably supported in a predetermined plane, table driving means for moving the table, and table position detection for detecting a table position in the predetermined plane On the other hand, the positioning hole position detection means detects the edge position of the image of the transmitted illumination light imaged by the imaging means, based on the edge position and the table position detected by the table position detection means, The center position of the positioning hole is detected. In this case, the positioning hole position detecting means detects the edge position of the image of the transmitted illumination light imaged by the imaging means, and performs positioning based on the edge position and the table position detected by the table position detecting means. Since the center position of the hole can be detected, the center position of the positioning hole can be detected more accurately.

The invention described in claim 8 is the invention according to claims 1 to 7
In the invention described in (1), the guide pin can be fixed to the optical fiber connector fixing member. In this case, when measuring the eccentricity of a plurality of optical connectors continuously, the optical connector to be measured can be easily exchanged without removing the guide pins. Time can be reduced, and continuous measurement can be easily performed.

The invention according to claim 9 is the invention according to claims 1 to 8
In the invention described in (1), the optical fiber connector fixing member is formed of epoxy resin.
In this case, the state of connection to the master optical connector made of epoxy resin can be reproduced, and more accurate measurement of the amount of eccentricity becomes possible.

According to a tenth aspect of the present invention, in the first to eighth aspects, the optical fiber connector fixing member is formed of a polyphenyl sulfide resin. In this case, the state of connection to the master optical connector formed of polyphenylsulfide resin can be reproduced, and more accurate measurement of the amount of eccentricity becomes possible.

According to an eleventh aspect of the present invention, in the ninth and tenth aspects of the present invention, the optical fiber connector fixing member comprises a pair of vertical wall portions arranged at a predetermined interval, and a vertical wall portion. And a positioning hole is formed in the horizontal wall portion, and the transmitted light from the optical fiber connector can be imaged by the imaging means. A transmission portion for transmitting the transmitted illumination light is formed between the positioning holes. In this case, the amount of eccentricity can be easily measured with the optical connector fixed to the optical fiber connector fixing member.

[0021]

Embodiments of the present invention will be described with reference to the drawings. 1 to 5 show an embodiment relating to an eccentricity measuring device for an optical connector according to the present invention.

FIG. 1 is a block diagram schematically showing an optical connector eccentricity measuring apparatus according to this embodiment.

The optical connector eccentricity measuring device includes a light-transmitting stage 101 made of glass or the like, a positioning jig 102 fixed on the stage 101, and a light source 103 for projecting light from below the stage 101. A CCD camera 104 serving as an image pickup means disposed above the stage 101; a calculation unit 105 for calculating the amount of eccentricity of the optical connector; and a TV monitor 106 for presenting an image picked up by the CCD camera 104. Stage 1
01 is provided with a pulse motor 107 for moving the stage 101 in a horizontal plane, and a laser length measuring device 108 for detecting the position of the stage 101 in the horizontal plane. The pulse motor 107 is a pulse motor drive circuit 1
09 is driven based on the signal from 09.

The arithmetic unit 105 includes the CCD camera 1
04 and an output signal from the laser measuring device 108 are input. In the arithmetic unit 105, the CCD camera 1
The eccentricity of the optical connector is calculated on the basis of the output signal (image information) from the optical disc 04 and the output signal (position information) from the laser length measuring device 108, while the CC on the TV monitor 106 is calculated.
An output signal is output to the TV monitor 106 so that the image captured by the D camera 104 is displayed.

The arithmetic unit 105 performs an arithmetic operation in accordance with a program stored in advance, and outputs a control signal for controlling the movement of the stage 101 to the pulse motor drive circuit 109. Further, an output signal as a control signal for controlling blinking of the light source 103 is output to the light source 103.

The case where the eccentricity of the fiber hole 111 of the ferrule 110 is measured by the optical connector eccentricity measuring apparatus according to the present invention will be described with reference to FIGS.

As shown in FIG. 2, the positioning jig 102 includes a pair of vertical wall portions 112 provided at predetermined intervals.
And a horizontal wall portion 113 provided continuously to the vertical wall portion 112, and are formed in a substantially U-shape. By fixing one set of vertical wall portions 112 to the stage 101 with an adhesive or the like,
The positioning jig 102 is fixed to the stage 101.
The guide pin 11 of the master optical connector is provided on the side wall 113.
A pair of positioning holes 114 having the same diameter and the same interval as the six holes are formed. Further, positioning holes 114 are formed in the side wall portion 113.
A rectangular hole 115 is formed between them. Rectangular hole 115
Is configured such that, when the ferrule 110 is mounted, the irradiation light is transmitted from the fiber hole 111 when the irradiation light is incident from the light source 103. Here, the master optical connector, for example, in the case of a 4MT connector, has a diameter of 0.3 mm.
When a guide pin made of stainless steel having a diameter of 6990-0.70000 mm is inserted, the force of pulling out the guide pin is 100 g, the distance between the two guide pin holes is 4.6 mm, and the core is Although the eccentricity of the part is close to 0, a general one is “JIS C5
961 Optical fiber connector test method ". The positioning hole 114 has a diameter of, for example, 0.6985 to
It is formed at an interval of 0.7005 mm, 4.6 ± 0.01 mm. In this case, the rectangular holes 115 are formed in the pitch direction by 3.
It is formed in a rectangular hole of 8 mm or less and 2 mm or less in a direction perpendicular to the pitch direction. The positioning jig 102 is formed of epoxy resin or polyphenyl sulfide resin. In this case, to improve durability,
The positioning holes 114 may be formed by inserting a cylindrical sleeve made of ceramic into the positioning jig 102.

When measuring the amount of eccentricity of the fiber hole 111 of the ferrule 110, the center position of the positioning hole 114 is calculated before attaching the ferrule 110 to the positioning jig 102. As shown in FIG. 2A, the center position of the positioning hole 114 is calculated by irradiating illumination light from below the stage 101 using the light source 103 and checking the situation with the CCD camera 104 above the positioning jig 102. This is done by imaging. Light incident from below the stage 101 passes through the positioning holes 114 and is received by the CCD camera 104. In the arithmetic unit 105, image information of the transmitted illumination light from the positioning hole 114 captured by the CCD camera 104 and the stage 10 detected by the laser length measuring device 108
The center position of the positioning hole 114 is calculated based on the position information.

FIG. 3 is a flowchart showing a control operation for calculating the center position of the positioning hole 114.

First, in S101, the positioning jig 102
It is determined whether or not is installed. This is because a switch that outputs an ON signal when the positioning jig 102 is fixed, or when an operator sets the O
N switches may be provided, and the determination may be made based on outputs from these switches. If the positioning jig 102 is installed (“Yes” in S101), the process proceeds to S103.

In step S103, the light source 103 is turned on, and illumination light is incident on the positioning jig 102. Following, S10
At 5, the CCD camera 104 captures image information of transmitted illumination light from the positioning hole 114. CCD camera 10
When imaging the transmitted illumination light from the positioning hole 114 at 4, the imaging is performed while the stage 101 is moved in the horizontal direction. In S107, edge processing is performed on the captured image, and the edge position of the positioning hole 114 is calculated.

In S109, the position information of the stage 101 is fetched from the laser length measuring device 108. Following, S11
At 1, the center position of the positioning hole 114 is calculated based on the calculated edge position and the table position obtained from the laser length measuring device 108. After calculating the center position of each positioning hole 114, the center position of each positioning hole 114 is stored in the memory in the arithmetic unit 105 in S113. Then, the process proceeds to S115, in which the light source 103 is turned off, and the control operation for calculating the center position of the positioning hole 114 ends.

After calculating the center position of the positioning hole 114, the ferrule 110 is attached to the positioning jig 102. To fix the ferrule 110, the ferrule 110 is positioned in a space between the vertical wall portions 112 of the positioning jig 102,
Positioning hole 114 and guide pin 11 of ferrule 110
This is performed by inserting the guide pins 116 from above the positioning jig 102 with the six holes aligned. When the ferrule 110 is attached to the positioning jig 102, the ferrule 110 that cannot be attached to the positioning jig 102 is excluded as a defective product. Positioning jig 10
2 is made based on the master optical connector and cannot be attached to the positioning jig 102 because the ferrule 110 cannot be connected to the master optical connector and cannot be used as an optical connector.

As shown in FIG. 2B, the center position of the fiber hole 111 is calculated by irradiating illumination light from below the stage 101 by using the light source 103 and checking the situation by the CCD above the positioning jig 102. This is performed by taking an image with the camera 104. Light incident from below the stage 101 passes through the fiber hole 111 and is received by the CCD camera 104. The arithmetic unit 105 includes image information of transmitted illumination light from the fiber hole 111 captured by the CCD camera 104 and the stage 10 detected by the laser length measuring device 108.
The center position of the fiber hole 111 is calculated based on the position information. Then, based on the center position of the positioning hole 114 and the center position of the fiber hole 111, the fiber hole 1
11 is calculated.

FIG. 4 is a flowchart showing a control operation for calculating the amount of eccentricity of the fiber hole 111.

First, in S201, it is confirmed whether or not the center position of the positioning hole 114 is stored in the memory. If the center position of the positioning hole 114 is stored in the memory ("Yes" in S201), the process proceeds to S203, and the stored center position of the positioning hole 114 is read from the memory. Next, in S205, it is determined whether or not the ferrule 110 is attached to the positioning jig 102. This may be achieved by providing a switch that turns on when the ferrule 110 is attached or a switch that is turned on by the operator after the ferrule 110 is attached, and making a determination based on the output from these switches. . If the ferrule 110 is attached (“Yes” in S205), the process proceeds to S207.

In step S207, the light source 103 is turned on, and illumination light is incident on the ferrule 110. Following, S209
Then, image information of transmitted illumination light from the fiber hole 111 of the ferrule 110 is captured from the CCD camera 104.
When imaging the transmitted illumination light from the fiber hole 111 with the CCD camera 104, the imaging is performed while the stage 101 is moved in the horizontal direction. In S211, edge processing is performed on the captured image to calculate the edge position of the fiber hole 111.

In step S213, the position information of the stage 101 is fetched from the laser length measuring device 108. Continue, S21
At 5, the center position of the fiber hole 111 is calculated based on the calculated edge position and table position. Finally, in S217, the eccentricity of the center position of the fiber hole 111 is calculated based on the center position of the positioning hole 114 read from the memory and the center position of the fiber hole 111 calculated in S215. The calculation of the amount of eccentricity of the center position of the fiber hole 111 is performed by setting the center of the line segment connecting the centers of the pair of positioning holes 114 as the connection center, the set position of each fiber hole center distributed from the connection center, and S215. This is performed by calculating the distance from the calculated center position of the fiber hole. The setting position of the fiber hole center is described in JIS C 59
81 F12 type multi-core optical fiber connector FIG. 1 ".

After calculating the amount of eccentricity of each fiber hole 111, the amount of eccentricity of each fiber hole 111 is stored in the memory in the arithmetic unit 105 in S219. afterwards,
Proceeding to S221, the light source 103 is turned off, and the control operation for calculating the eccentric amount of the fiber hole 111 ends.

Positioning hole 114 or fiber hole 11
In calculating the center position of the stage 1, the stage 101
Is used. This is because, in order to calculate the center position of the positioning hole 114 or the fiber hole 111 more accurately, the CCD camera 104 is basically fixed in the horizontal direction, and the positioning hole 114 or the fiber hole 111 is enlarged. This is because the technique of taking an image of a part of the image and moving the stage 101 to take an image of the entire hole is taken.

According to the optical connector eccentricity measuring apparatus described above, the positioning jig 1 based on the master optical connector is used.
02, the eccentricity of the center position of the fiber hole 111 of the ferrule 110 was measured, so that the measurement was performed in the same state as the state connected to the master optical connector, and an accurate eccentricity was obtained. Can be

Further, the illumination light is incident on the guide pin hole of the ferrule 110 to image the transmitted illumination light, and there is no need to detect the center position based on the captured image. The time for measuring the eccentric amount of the center position of the fiber hole 111 as a reference is reduced. Usually, the ferrule 110 is continuously inspected at the factory, but if the center position of the positioning hole 114 is calculated and stored at the start of the inspection work, the subsequent inspection is performed for the stored positioning hole 11.
This is because the calculation can be performed based on the center position of No. 4 and therefore it is not necessary to actually image the guide pin hole of the ferrule 110. Further, the optical connector 11 is attached to the positioning jig 102.
Since the measurement can be started by fixing 7, the measurement of the amount of eccentricity becomes easy.

Since the positioning jig 102 is formed of an epoxy resin or a polyphenylsulfide resin used as a ferrule material of a master optical connector or the like, a state connected to the master optical connector can be reproduced.
More accurate measurement of the amount of eccentricity becomes possible. When the positioning hole 114 is formed by inserting a cylindrical sleeve made of ceramic into the positioning jig 102, the durability can be improved.

Next, a case where the eccentricity of the core portion of the optical fiber 118 of the optical connector 117 is measured by the optical connector eccentricity measuring apparatus according to the present invention will be described with reference to FIG. In the present embodiment, description will be made based on a configuration in which ferrules 110 are attached to both ends of an optical fiber 118 to form optical connectors 117, respectively.

The positioning jig 102 includes a ferrule 110
The same one as that for measuring the amount of eccentricity of the fiber hole 111 is used. Before attaching the ferrule 110 to the positioning jig 102, as shown in FIG. 5A, the center position of the positioning hole 114 is calculated, which is used when the eccentricity of the fiber hole 111 of the ferrule 110 is measured. The illumination light is incident from below the stage 101 using the light source 201, and the situation is imaged by the CCD camera 104 above the positioning jig 102. Light incident from below the stage 101 passes through the positioning holes 114 and is received by the CCD camera 104. In the arithmetic unit 105, image information of transmitted illumination light from the positioning hole 114 captured by the CCD camera 104 and the stage 1 detected by the laser length measuring device 108
The center position of the positioning hole 114 is calculated based on the position information No. 01. The arithmetic unit 105 calculates the center position of the positioning hole 114 based on the same flowchart as the control operation for calculating the center position of the positioning hole 114 shown in FIG.

After calculating the center position of the positioning hole 114, one optical connector 117 is attached to the positioning jig 102. The fixing of the optical connector 117 is performed by using the positioning jig 1.
In a state where the optical connector 117 is located in the space between the vertical wall portions 112 of the optical connector 02 and the positioning hole 114 and the guide pin 116 hole of the optical connector 117 are aligned, the positioning jig 1
This is performed by inserting the guide pin 116 from the upper side of O.2. When attaching the optical connector 117 to the positioning jig 102, the optical connector 117 that cannot be attached to the positioning jig 102 is excluded as a defective product. The positioning jig 102 is made based on the master optical connector. The fact that the positioning jig 102 cannot be attached to the positioning jig 102 means that the optical connector 117 cannot be connected to the master optical connector and cannot be used as an optical connector. Because.

As shown in FIG. 5B, the center position of the core of the optical fiber 118 is calculated by connecting the other optical connector 117 to the light source 201, guiding the illumination light from the light source 201, The situation is the CCD above the positioning jig 102
This is performed by taking an image with the camera 104. Illumination light from the light source 201 is transmitted from the core of the optical fiber 118 to the CCD camera 104.
Is received by the The arithmetic unit 105 determines the center of the core based on the image information of the transmitted illumination light from the core of the optical fiber 118 captured by the CCD camera 104 and the position information of the stage 101 detected by the laser measuring device 108. Calculate the position. Then, the eccentricity of the core is calculated based on the center of the positioning hole 114 and the center of the core.

The arithmetic unit 105 calculates the edge position of the core in the same steps as those in the flowchart showing the control operation for calculating the eccentricity of the fiber hole 111 shown in FIG. 4, and calculates the calculated edge position. The center position of the core part is calculated based on the table position and the table position. Thereafter, the eccentricity of the center position of the core is calculated based on the center position of the positioning hole 114 read from the memory and the calculated center position of the core. The calculation of the amount of eccentricity of the center position of the core portion is performed by setting a center point of a line connecting the centers of the pair of positioning holes 114 as a connection center, a set position of each core portion distributed from the connection center, and a center of the core portion. This is performed by calculating the distance from the position. The setting position of the center of the core is “JIS C
5981 F12 type multi-core optical fiber connector This is the same as the setting position of the center of the fiber hole described in FIG.

In calculating the center position of the positioning hole 114 or the core, the position information of the stage 101 is used. This is because, in order to more accurately calculate the center position of the positioning hole 114 or the core, the CCD camera 104 is basically fixed in the horizontal direction, and the positioning hole 114 or the core is enlarged and the hole or the core is enlarged. This is because a method is used in which a part of the part is imaged and the stage 101 is moved to image the hole or the entire core.

According to the optical connector eccentricity measuring device described above, the positioning jig 1 made based on the master optical connector is used.
02, the eccentricity at the center position of the core of the optical fiber 118 was measured. Therefore, the measurement was performed in the same state as when the optical fiber 118 was connected to the master optical connector, and an accurate eccentricity was obtained. Can be

Further, it is not necessary to input illumination light to the guide pin hole of the optical connector 117 to capture transmitted illumination light, and to detect the center position based on the captured image. The time required to measure the amount of eccentricity of the center position of the core with reference to is reduced. Normally, the optical connector 117 is continuously inspected at the factory, but if the center position of the positioning hole 114 is calculated and stored at the start of the inspection work or the like, the subsequent inspection is performed at the center position of the stored positioning hole 114. Can be calculated based on the optical connector 11.
This is because there is no need to image the guide pin hole 7. Furthermore, since the measurement can be started by fixing the optical connector 117 to the positioning jig 102, the measurement of the amount of eccentricity is facilitated.

Since the positioning jig 102 is formed of epoxy resin or polyphenylsulfide resin used as a ferrule material of a master optical connector or the like, it can reproduce a state connected to the master optical connector.
More accurate measurement of the amount of eccentricity becomes possible. When the positioning hole 114 is formed by inserting a cylindrical sleeve made of ceramic into the positioning jig 102,
Durability can be improved.

FIG. 6 shows a modification of the stage for fixing the positioning jig 102. This stage 301
It is used to measure the amount of eccentricity of the center position of the fiber hole 111 or the core with respect to a large amount of ferrule 110 or optical connector 117.

The stage 301 has a first stage 302 on which a plurality of positioning jigs 102 are fixed in a matrix with an adhesive or the like, and a second stage 303 on which the first stage 302 is mounted. . The first and second stages 303 are translucent members such as glass, and are formed in a rectangular shape. On the second stage 303, a first fixing member 304 and a second fixing member 305 are provided on a diagonal line of a surface on which the first stage 302 is mounted. The first fixing member 304 is a substantially L-shaped member, and the second stage 303
It is fixed to. The second fixing member 305 is connected to the first member 3
06 and a second member 307. First member 3
Reference numeral 06 denotes a second stage 30 at a corner diagonally opposite to the corner to which the first fixing member 304 is fixed.
It is fixed to 3. The second member 307 includes the first member 30
6 is supported via an elastic member 308 such as a spring,
The second stage 303 is provided movably on the surface on which the first stage 302 is placed. Second member 3
07 is also formed in a substantially L-shape similarly to the first fixing member 304.

The first stage 302 is replaced with the second stage 303
When the first stage 302 is mounted, one corner of the first stage 302 is first brought into contact with the first fixing member 304 and positioned. Thereafter, the corner positioned by the first fixing member 304 and the opposite corner on the diagonal line are connected to the second fixing member 3.
The second member 307 is fixed while positioning.
Accordingly, the first stage 302 is supported by the first member 306 by the elastic force of the elastic member 308.

The use of the stage 301 makes it possible to measure the amount of eccentricity of the fiber hole 111 with respect to a large number of ferrules 110.

The CCD camera 104 used in the above-described embodiment is preferably equipped with a microscope because it is necessary to magnify and image the fiber hole 111 and the like.

The rectangular hole 11 formed in the positioning jig 102
5 is not limited to a rectangular shape, but may be an elliptical hole, since the illumination light from the light sources 103 and 201 may be formed.

Guide pins 116 for fixing positioning jig 102 to ferrule 110 or optical connector 117
May be configured to be detachable and fixable to the positioning jig 102. With this configuration, after calculating the center position of the positioning hole 114, the guide pin 1
By inserting 16 into the positioning jig 102 and fixing it,
When continuously measuring the eccentricity of the plurality of ferrules 110 or the optical connectors 117, it is not necessary to remove the guide pin 116 each time, and the eccentricity can be measured in a shorter time.

The calculated eccentricity of the fiber hole 111 or the core of the optical fiber 118 is calculated by the arithmetic unit 105.
It is configured to be stored in the memory inside the
A signal indicating the amount of eccentricity may be output to the monitor 106 and displayed on the screen, or the eccentricity may be compared with a reference value to determine whether the product is non-defective, and the result of the determination may be stored or displayed. You may be comprised so that it may be performed.

As an inspection of the optical connector 117, the optical connector 117 is connected to the master optical connector, the reference light is guided from the master optical connector side, and the output loss of the reference light is measured. If the output loss is equal to or more than a predetermined value, it is excluded as a defective product. According to the above-described eccentricity measuring apparatus for an optical connector, the eccentricity of the center position of the fiber hole 111 or the core portion with reference to the center position of the guide pin hole of the master optical connector is also measured. Therefore, if the correlation between the amount of eccentricity and the output loss is determined in advance by an experiment or the like, it is possible to derive the output loss at the time of connection with the master optical connector only by measuring the amount of eccentricity.
By using the optical connector eccentricity measuring apparatus described above, there is also a possibility that the above-described step of actually connecting to the master optical connector for measurement can be eliminated.

[0062]

As described above in detail, according to the present invention, the eccentricity of the fiber hole or the core of the optical fiber inserted into the fiber hole can be easily measured, and the measurement time can be shortened. It is possible to provide a simple optical fiber connector eccentricity measuring device.

[Brief description of the drawings]

FIG. 1 is a block diagram schematically showing an optical connector eccentricity measuring apparatus according to an embodiment of the present invention.

FIG. 2 is a schematic diagram of a configuration of an optical connector eccentricity measuring device used for measuring the eccentricity of a fiber hole according to an embodiment of the present invention.

FIG. 3 is a flowchart illustrating a control operation of the arithmetic unit according to the embodiment of the present invention.

FIG. 4 is a flowchart illustrating a control operation of the arithmetic unit according to the embodiment of the present invention.

FIG. 5 is a schematic configuration diagram of an optical connector eccentricity measuring device used when measuring the amount of eccentricity of a core portion of an optical fiber according to an embodiment of the present invention.

FIG. 6 is a perspective view showing a modification of the stage for fixing the positioning jig according to the embodiment of the present invention.

FIG. 7 is a perspective view showing a conventional optical connector (when not connected).

FIG. 8 is a schematic configuration diagram showing a conventional optical connector eccentricity measuring device.

[Explanation of symbols]

101, 301: stage, 102: positioning jig, 1
03, 201: light source, 104: CCD camera, 105:
Arithmetic unit, 108: laser length measuring device, 110: ferrule, 111: fiber hole, 112: vertical wall portion, 11
3 ... side wall part, 114 ... positioning hole, 115 ... rectangular hole, 1
16: guide pin, 117: optical connector, 118: optical fiber.

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Toshiaki Kakii 1-chome, Taya-cho, Sakae-ku, Yokohama-shi, Kanagawa F-term (reference) in Yokohama Works, 2F065 AA17 CC23 DD06 FF04 FF52 HH15 JJ03 JJ26 LL03 QQ24 QQ31 2G086 AA02 KK02 KK07 2H036 JA02 QA00 QA49

Claims (11)

[Claims] 1. An eccentricity measuring apparatus for an optical fiber connector in which an optical fiber connector having a guide pin hole and a fiber hole is formed, the eccentricity of the position of the fiber hole is measured with reference to the position of the guide pin hole. A set of positioning holes having the same inner diameter and spacing as the set of guide pin holes formed in the master optical connector is formed, and the guide pins inserted into the positioning holes are connected to the optical fiber connector. An optical fiber connector fixing member for fixing the optical fiber connector by being inserted into a guide pin hole; an illumination light incident means for entering illumination light into the fiber hole on one side of the fiber hole; On the other side, image the transmitted illumination light from the fiber hole of the optical fiber connector fixed to the optical fiber connector fixing member A fiber hole position detecting means for detecting a center position of the fiber hole based on the transmitted illumination light from the fiber hole imaged by the image capturing means; and an optical fiber connector fixing prepared in advance. Based on the center position of the positioning hole of the member and the center position of the fiber hole detected by the fiber hole position detecting means, the amount of eccentricity of the center position of the fiber hole with respect to the position of the guide pin hole is determined. An eccentricity measuring device for an optical fiber connector, comprising: an eccentricity measuring means for measuring. 2. A table on which the optical fiber connector fixing member is fixed and supported movably in a predetermined plane; table driving means for moving the table; and a table for detecting a table position in the predetermined plane. The fiber hole position detecting means detects an edge position of the image of the transmitted illumination light imaged by the imaging means, and the table detected by the edge position and the table position detecting means. The optical fiber connector eccentricity measuring apparatus according to claim 1, wherein a center position of the fiber hole is detected based on the position. 3. The illumination light incident means enters illumination light into the positioning hole on one side of the positioning hole, and the imaging means transmits transmitted illumination light from the positioning hole on the other side of the positioning hole. A positioning hole position detection unit that captures an image and detects a center position of the positioning hole based on the transmitted illumination light captured by the imaging unit; and stores a center position of the positioning hole detected by the positioning hole position detection unit. The eccentricity measurement means reads the center position of the positioning hole stored in the storage means, and is detected by the read center position of the positioning hole and the fiber hole position detection means. And measuring the eccentricity of the center position of the fiber hole with reference to the position of the guide pin hole based on the center position of the fiber hole. Eccentricity measuring apparatus for an optical fiber connector according to. 4. An optical fiber connector in which a guide pin hole and a fiber hole are formed and an optical fiber is inserted and fixed in said fiber hole, wherein said optical fiber is positioned with respect to the position of said guide pin hole. An eccentricity measuring device for an optical fiber connector for measuring an eccentricity of a position of a core portion, wherein a set of positioning holes having the same inner diameter and spacing as a set of guide pin holes formed in a master optical connector are formed. An optical fiber connector fixing member for fixing the optical fiber connector by inserting the guide pin hole of the optical fiber connector into the guide pin inserted in the positioning hole, and one end fixed to the optical fiber connector Illumination light incident means for inputting illumination light to the optical fiber at the other end of the optical fiber, On the end face side of the optical fiber connector in which the hole is formed, an imaging means for imaging transmitted illumination light from a core part of the optical fiber fixed to the optical fiber connector fixing member, and the imaging means which is imaged by the imaging means Core part position detecting means for detecting a center position of the core part based on transmitted illumination light from the core part; a center position of a positioning hole of the optical fiber connector fixing member prepared in advance; and the core part position An eccentricity measuring means for measuring an eccentricity of a center position of the core portion with reference to a position of the guide pin hole based on the center position of the core portion detected by the detecting device. Optical fiber connector eccentricity measuring device. 5. A table to which the optical fiber connector fixing member is fixed and movably supported in a predetermined plane, table driving means for moving the table, and a table for detecting a table position in the predetermined plane The core portion position detecting means detects an edge position of an image of the transmitted illumination light imaged by the imaging means, and the table detected by the edge position and the table position detecting means. The eccentricity measuring device for an optical fiber connector according to claim 4, wherein a center position of the core portion is detected based on the position. 6. The illumination light incident means enters illumination light into the positioning hole on one side of the positioning hole, and the imaging means transmits transmitted illumination light from the positioning hole on the other side of the positioning hole. A positioning hole position detection unit that captures an image and detects a center position of the positioning hole based on the transmitted illumination light captured by the imaging unit; and stores a center position of the positioning hole detected by the positioning hole position detection unit. The eccentricity measurement means reads the center position of the positioning hole stored in the storage means, and is detected by the read center position of the positioning hole and the core position detection means. 5. The optical fiber according to claim 4, wherein an eccentric amount of the center position of the core portion with respect to the guide pin hole position is measured based on the center position of the core portion. Driver connector eccentricity measuring apparatus. 7. A table to which the optical fiber connector fixing member is fixed and movably supported in a predetermined plane; table driving means for moving the table; and a table for detecting a table position in the predetermined plane. The positioning hole position detecting means detects an edge position of the image of the transmitted illumination light imaged by the imaging means, and detects the edge position and the table detected by the table position detecting means. The eccentricity measuring device for an optical fiber connector according to claim 3, wherein a center position of the positioning hole is detected based on the position. 8. The eccentricity measuring device for an optical fiber connector according to claim 1, wherein the guide pin is fixable to the optical fiber connector fixing member. . 9. The optical fiber connector eccentricity measuring apparatus according to claim 1, wherein the optical fiber connector fixing member is formed of epoxy resin. 10. The optical fiber connector fixing member,
The eccentricity measuring device for an optical fiber connector according to any one of claims 1 to 8, wherein the device is formed of a polyphenyl sulfide resin. 11. The optical fiber connector fixing member,
A pair of vertical wall portions arranged at predetermined intervals and a horizontal U-shaped portion formed of a horizontal wall portion provided continuously with the vertical wall portion are formed in a substantially U-shape. 10. A hole is formed, and a transmitting portion for transmitting transmitted illumination light is formed between the positioning holes so that the transmitted light from the optical fiber connector can be imaged by the imaging means. The eccentricity measuring device for an optical fiber connector according to any one of claims 1 to 10.