JPH0827416B2 - Precision measurement method for multi-core connector - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a multi-core connector, and in a multi-core connector, precisely measures the center position of a fiber insertion hole and a pin hole into which a guide pin is fitted. Regarding the method.

(Prior Art) A multi-core connector is one in which a guide pin is fitted in a pin hole of a mating multi-core connector and butt-connected, and for example,
The optical fiber of the multi-core fiber is inserted into each of a plurality of fiber insertion holes formed in a plastic ferrule at a constant array pitch, and these are fixed with an adhesive.

In such a multi-core connector, it is necessary to precisely form and process each fiber insertion hole in a submicron order in order to reduce the connection loss due to the butt connection with another multi-core connector as much as possible. Therefore, the center position of each fiber insertion hole in the manufactured ferrule is measured for the purpose of quality control of the multi-fiber connector.

However, in such a measurement, when the fiber insertion hole is measured with reflected illumination, a problem that a measurement error that is unacceptable in the sub-micro order occurs when the peripheral edge of the fiber insertion hole is missing or the hole shape is distorted. was there.

Therefore, the measurement light is normally incident from the rear of each hole so as not to be affected by the shape of the exit side of each fiber insertion hole or the internal shape. That is, an optical fiber is inserted into each fiber insertion hole and fixed by adhesion, and the measurement light incident from the light source side at one end is measured at the abutting surface of the ferrule at the other end to accurately measure the center position of each fiber insertion hole. I'm measuring.

(Problems to be solved by the invention) By the way, in the measurement of the fiber insertion hole in the multi-core connector, the position based on the pin hole is important because the guide pin and the pin hole are butt-connected by fitting. However, there is a problem that the measurement of such pin holes must be performed separately due to the difference in hole diameter and the like, and the measurement work is very complicated.

The present invention has been made in view of the above points, and it is an object of the present invention to provide a precision dimension measuring method for a multi-core connector, which can collectively measure the position of a pin hole together with the position of each fiber insertion hole with high accuracy. To aim.

(Means for Solving the Problems) In order to achieve the above object, according to the precision dimension measuring method for a multi-core connector of the present invention, a butt end face, a pin hole opening at the butt end face, and a plurality of optical fibers are provided. A single-core ferrule having an optical fiber attached to the pin hole of a multi-core connector having a multi-core fiber exposed and attached to a butt end face is removably inserted and attached, and the position of the multi-core connector is set within a predetermined plane. In the position measuring means which is adjustable in two axial directions, and the transmitting / receiving ferrule to which the transmitting / receiving fiber is attached is butted to the multi-core connector, with respect to the transmitting / receiving fiber of the transmitting / receiving ferrule,
The position of each optical fiber attached to the multi-core fiber is adjusted to a plurality of positions for each optical fiber by the position measuring means, and at each adjusted position of each optical fiber, the transmission / reception fiber is moved from the arbitrary optical fiber. The measuring light transmitted therethrough is sequentially measured, and the center positions of the pin hole and each optical fiber are precisely measured.

Here, as the single-core ferrule and the optical fiber, those having no eccentricity in the ferrule outer diameter and the core outer diameter are used.

As the light source of the measurement light, for example, a light source such as an LED or a semiconductor laser with little fluctuation in light intensity is used.

Further, as the position measuring means for measuring the position of the multi-core connector adjusted in the biaxial direction, an optical stage capable of finely adjusting the position in the biaxial direction, for example, displaying the position in the X, Y2 axis directions is displayed. An XY stage equipped with a scale is used.

At this time, the scale is adjusted in position in the two axial directions by the scale controller, and the initial position is determined. Further, the position of the XY stage itself can be finely adjusted in the biaxial directions by manual operation, and can also be mechanically finely adjusted by, for example, a stage controller.

Furthermore, the light intensities at the plurality of adjustment positions are obtained by, for example, an optical power meter.

(Operation) When the single-core ferrule is inserted into the pin hole of the multi-core connector, the multi-fiber and the single ferrule optical fiber are exposed at the butt end face of the multi-core connector.

For each of these optical fibers, the position of the light transmitting / receiving ferrule with respect to the light transmitting / receiving fiber is adjusted to a plurality of positions by the position measuring means. The position measuring means adjusts the position of the multi-core connector so that the light intensities at the respective adjusting positions become equal.

If each optical fiber of the multi-core connector is a perfect circle with no eccentricity in the outer diameter of the core, each adjustment position is located on the circumference equidistant from the center of the core of the optical fiber.

Therefore, based on these adjustment positions, the center position of each optical fiber of the multi-core connector, that is, the pin hole of the multi-core connector and the center position of the core for each optical fiber of the multi-fiber connector are obtained.

(Embodiment) An embodiment of the present invention will be described below in detail with reference to FIG. 1 and FIG.

FIG. 1 shows the structure of a dimension measuring system for carrying out the method of the present invention. The dimension measuring system comprises an XY stage 1, a scale 2 and a support frame 3.

As shown in the drawing, the XY stage 1 has a rectangular mounting hole 1a formed in the center thereof so as to vertically penetrate therethrough and to which the multi-core connector 4 to be measured is mounted. This stage 1 has a mounting hole
Together with the multi-core connector 4 attached to 1a, it can be finely moved in the X and Y directions in the figure, and is moved in the two X and Y axis directions by the stage controller 5 shown in FIG. As a result, the position of the multi-core connector 4 in the XY directions is finely adjusted.

As shown in FIG. 1, the multi-core connector 4 has a multi-core fiber 6 attached to a main body 4a, and one end of each optical fiber 6a is exposed at the butt end face 4b. Multi-fiber 6
The other end is connected to a light source 7 (see FIG. 2) using an LED. Further, pin holes 4c and 4c are formed on both sides of the main body 4a where the ends of the respective optical fibers 6a are exposed, and the respective pin holes 4c are formed.
The single-core ferrule 8 is attached to the c so as to be freely inserted and removed.

The single-core ferrule 8 is for measuring the center position of the pin hole 4c, and one end thereof is attached to the other end of the optical fiber 9 connected to the light source 7.

The scale 2 displays the position of the XY stage 1 which is attached with the multi-core connector 4 and is slightly moved in the XY directions.
When adjusting the position in the XY directions by the scale controller 10 shown in FIG. 2 and measuring the multi-core connector 4,
Positioning to the initial position is performed.

The support frame 3 mounts and supports the light-transmitting / receiving ferrule 11, and as shown by an arrow Z in FIG. 1, moves in a direction orthogonal to a plane defined by the XY stage 1 to transmit the light. The light receiving ferrule 11 is butted with the multi-core connector 4.

The light transmitting / receiving ferrule 11 is attached to the other end of the light transmitting / receiving fiber 13 whose one end is connected to the optical power meter 12 (see FIG. 2). It is optically connected to any of the plurality of optical fibers 6a and 9 attached to the multi-core connector 4.

The optical power meter 12 measures the light intensity of the measurement light from the light source 7 transmitted through the light transmitting / receiving fiber 13. The light intensity measured by the optical power meter 12 is converted into a predetermined signal and input to a computer (ECU) 14, and the position of the core center of each optical fiber 6a, 9 is calculated.

As shown in FIG. 2, the stage controller 5, the light source 7, the scale controller 10, and the optical power meter 12 are connected to a computer 14, and their operations are controlled by the computer 14.

The precision dimension measuring method of the multi-core connector of the present invention is executed as follows using the above measuring system.

First, the single-core ferrule 8 is inserted into each pin hole 4c of the multi-core connector 4 so as to be substantially flush with the butt end face 4b.

Next, attach the multi-core connector 4 to the mounting hole 1a of the XY stage 1.
And the supporting frame 3 is lowered. As a result, the transmitting / receiving ferrule 11 is butted to the butting end face 4b of the multi-core connector 4, and the sending / receiving fiber 13 is attached to the first optical fiber of the plurality of optical fibers 6a and 9 for which the position of the core center is to be obtained. Approximate butt connection.

At this time, the light transmitting / receiving ferrule 11 does not have to be completely brought into close contact with the multi-fiber connector 4, and may be held constant while measuring the measurement light from a predetermined optical fiber.
In such a state of the general connection, the intensity of the measurement light measured by the optical power meter 12 is P _A.

Then, the XY stage 1 is moved in an arbitrary direction within the range of the first optical fiber, and the intensity of the measurement light measured by the optical power meter 12 becomes, for example, (P _A -1) dB. The XY stage 1 is stopped at the position. The coordinate position (X ₁₁ , Y ₁₁ ) on the XY stage 1 at this time is read on the scale 2.

After that, the XY stage 1 is moved to another position within the range, and similarly, the intensity of the measurement light is (P _A -1).
Read the coordinate position (X ₁₂ , Y ₁₂ ) to be dB.

Hereinafter, such work will be described with reference to the first optical fiber.
Repeated (n ≧ 3) times, n coordinate positions are measured as shown in FIG. These n points are points at which the transmission loss of the measurement light is equal, and are located on the circumference equidistant from the center O of the core in the first optical fiber. Here, in FIG. 3, the point I _P is the initial position when the intensity of the measurement light becomes P _A when the transmitting and receiving fibers 13 are roughly butt-connected.

Therefore, based on the n points, the following equations regarding the core center ( ₁₀ , ₁₀ ) and the radius R of the first optical fiber are derived from the equation of the circle.

Based on the above equation, the center of the core ( ₁₀ , ₁₀ ) of the first optical fiber is calculated by the computer system 14 by the least square method.
Calculate with.

Similarly, if the positions of the core centers of the other optical fibers 6a and 9 corresponding to the second to nth optical fibers are obtained, a plurality of cores of the guide pin holes 4c and 4c of the multi-core connector 4 are used as a reference. The position of the core center of the optical fiber 6a is obtained.

This makes it possible to know the amount of misalignment of the fiber insertion hole of the multi-core connector 4 with reference to the guide pin holes 4c, 4c.

According to the method of the present invention, a laser scale having an accuracy of 0.1 μm or less was used, and the core positions of the plurality of optical fibers 6a were measured, and an accuracy of 0.1 μm was obtained.

In the above embodiment, the optical power meter was used to obtain the intensities of the measuring light at a plurality of positions, and the central position of each optical fiber was calculated based on the measured positions. However, it goes without saying that the center position of each optical fiber may be obtained by, for example, photographing the emission end face of each optical fiber with an additional camera and subjecting this image to image processing.

(Effects of the Invention) As is clear from the above description, according to the precision dimension measurement of the multi-fiber connector of the present invention, it is possible to collectively measure each optical fiber position together with the pin hole position with high accuracy. It has an excellent effect that the position of each optical fiber can be measured with the position of the hole as a reference.

[Brief description of drawings]

FIGS. 1 and 2 explain one embodiment of the method of the present invention. FIG. 1 is a schematic configuration diagram relating to the mechanical configuration of a measurement system for carrying out the method of the present invention, and FIG. 2 is FIG. FIG. 3 is a schematic connection diagram of the measurement system of FIG. 3, and FIG. 3 is an explanatory view showing measurement of the pin hole of the multi-core connector and the center position of each optical fiber. 1 ... XY stage (position measuring means), 4 ... multi-core connector, 4b ... butt end face, 4c ... pin hole, 6 ... multi-core fiber, 6a ... optical fiber, 8 ... single core Ferrule,
8a ... optical fiber, 11 ... sending and receiving ferrule, 12 ... optical power meter, 13 ... sending and receiving fiber.

Claims (1)

[Claims] 1. A multi-core connector having a butt end face, a pin hole opening in the butt end face, and a multi-core fiber mounted with the plurality of optical fibers exposed at the butt end face.
A single-core ferrule having an optical fiber attached to the pin hole is removably inserted and attached, and the position of the multi-core connector is attached to position measuring means which is adjustable in two axial directions within a predetermined plane, and the optical fiber Butt the light-transmitting and receiving ferrules attached to the multi-fiber connector, the position of each optical fiber attached to the multi-fiber to the light-receiving fiber of the light-receiving ferrule, a plurality of positions for each optical fiber by the position measuring means. The measurement light transmitted from the arbitrary optical fiber through the light transmitting / receiving fiber is sequentially measured at each adjustment position of each optical fiber, and the center position of the pin hole and each optical fiber is precisely measured. A method for measuring precision dimensions of a multi-core connector, which is characterized in that