JPH04190306A - Measuring method for multicore connector dimension - Google Patents

Abstract

PURPOSE:To enable measurement of pin hole positions collectively with the respective fiber inserting hole positions by inserting a monocore ferrule provided with optical fibers into pin holes of multicore connectors, and measuring the center positions of the optical fiber of the monocore ferrule and of the respective optical fibers of multicore fibers. CONSTITUTION:When a monocore ferrule 8 is inserted into a pin hole 4c of a multicore connector 4, the respective optical fibers 6a, 9 of the multicore fiber 6 and the monocore ferrule 8 are exposed respectively on the abutting end surface 4b of the multicore connector 4. There is obtained the position relationship of the pin hole 4c of the multicore connector 4 and the respective optical fibers 6a of the multicore fibers, by making measurement of the center positions for the respective optical fibers. In this case, the monocore ferrule provided with the optical fiber is inserted into the pin hole of the multicore connector, and this enables collective measurements of the respective optical fiber positions with the pin hole positions without employing any other method. This constitution makes it unnecessary to make individual measurements of the pin hole positions and the respective optical fiber positions, providing an excellent effect to obtain the respective optical fiber positions easily relative to the pin hole.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a method for measuring the dimensions of a multi-fiber connector, which measures the positions of a fiber insertion hole and a pin hole into which a kite pin is fitted in the multi-fiber connector.

(Prior art) Multi-fiber connectors are butt-connected by fitting guide pins into the pin holes of the mating multi-fiber connector. Each optical fiber of the multicore fiber is inserted into each hole, and these are fixed with adhesive.

In such a multi-fiber connector, each fiber insertion hole needs to be precisely formed on the submicron order in order to reduce connection loss due to butt connection with other multi-fiber connectors as much as possible. Therefore, for the purpose of quality control of multi-fiber connectors, the position of each fiber insertion hole in the manufactured ferrule is measured.

However, when measuring the fiber insertion hole using reflected illumination in such measurements, there is a problem that measurement errors that cannot be tolerated on the submicron order occur when the periphery of the fiber insertion hole is missing or the hole shape is distorted. was there.

For this reason, the measurement light is normally entered from behind the hole so as not to be affected by the shape of the output side or the internal shape of each fiber insertion hole. In other words, the position of each fiber insertion hole can be precisely measured by inserting an optical fiber into each fiber insertion hole and fixing it with adhesive, and measuring the measurement light incident from the light source side at one end at the abutting surface of the ferrule at the other end. are doing.

(Problems to be Solved by the Invention) By the way, when measuring the fiber insertion hole in a multi-core connector, the position with respect to the pin hole is important because a butt connection is made by fitting a guide pin and a pin hole. However, the measurement of such pin holes has to be carried out separately due to differences in hole diameter, etc., and there is a problem in that 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 method for measuring the dimensions of a multi-fiber connector that can measure the position of the pin hole together with the position of each fiber insertion hole. .

(Means for Solving the Problems) In order to achieve the above object, according to the multi-core connector dimension measuring method of the present invention, an optical fiber is inserted into the pin hole of a multi-core connector having a pin hole and a multi-core fiber. By inserting the attached single-core ferrule and measuring the optical fiber of the single-core ferrule and the center of each optical fiber of the multi-core fiber, the center of the pin hole and the center of each optical fiber of the multi-core fiber can be determined. The configuration is such that the positional relationship between the two is determined.

Preferably, image processing using an imaging camera is used as the measuring means for measuring the center of each optical fiber.

Here, the single-core ferrule and the optical fiber have no eccentricity in the outer diameter of the ferrule and the outer diameter of the core, respectively.

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

In addition, as a position measuring means for measuring the position of a multi-core connector that is adjusted in two axes, an optical stage that can finely adjust the position in two axes, for example, displays the position in two X and Y axes. An X-Y stage equipped with a scale is used.

At this time, the scale controller adjusts the position of the scale in two axial directions to determine the initial position. In addition, the X-Y stage itself can be manually operated in two
In addition to being able to finely adjust the position in the axial direction, it is also possible to finely adjust the position mechanically using, for example, a stage controller.

Furthermore, as a measurement means for measuring the center of each optical fiber,
There are means for measuring the intensity of the measurement light transmitted through the optical fiber of the multi-core connector using a power meter, for example, or for image processing using an imaging camera.

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

By measuring the center position of each of these optical fibers, the positional relationship between the pin hole of the multi-core connector and each optical fiber of the multi-core fiber is determined.

(Example) Hereinafter, an example of the present invention will be described in detail with reference to FIGS. 1 and 2.

FIG. 1 shows the configuration of a dimension measuring system for implementing the method of the present invention, and the dimension measuring system is equipped with an X-Y stage 1, a scale 2, and a support frame 3.

As shown in the figure, the X-Y stage 1 has a rectangular mounting hole 1a that passes vertically through the center and mounts the multi-core connector 4 to be measured. This stage 1, together with the multi-core connector 4 installed in the mounting hole 1a,
The stage controller 5 shown in FIG. 2 allows fine movement in the Y direction.

It is moved in two axis directions of Y. Thereby, the position of the multi-core connector 4 in the X-Y direction is finely adjusted.

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

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

The scale 2 displays the position of the l'-Y stage 1 (with the multi-core connector 4 attached and slightly moved in the X-Y direction), and is controlled by the scale controller lO shown in FIG.
When adjusting the position in the Y direction and measuring the multi-core connector 4, positioning to the initial position is performed.

The support frame 3 attaches and supports the light transmission/reception ferrule 11, and moves in a direction perpendicular to the plane defined by the X-Y stage 1, as shown by arrow Z in FIG. The light receiving ferrule 11 is butted against the multi-core connector 4.

The transmitting and receiving light ferrule 11 has one end connected to the optical power meter 12 (
The transmitting/receiving optical fiber 13 is connected to the other end of the transmitting/receiving optical fiber 13 connected to Optical connection is made to either 6a or 9.

The optical power meter 12 measures the optical intensity of the measurement light from the light source 7 transmitted through the optical transmitting/receiving fiber I3. The light intensity measured by the optical power meter 12 is converted into a predetermined signal and input to the computer (ECU) 14. The computer 14 determines the position where the light intensity is maximum based on the signal related to the light intensity transmitted from the optical power meter 12.

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

The multi-core connector dimension measuring method of the present invention is carried out as follows using the above measurement system.

First, the single-core ferrule 8 is inserted into each of the via holes 4C of the multi-core connector 4 so that the abutted end faces 4b and the road surface are aligned with each other.

Next, attach the multi-core connector 4 to the mounting hole 1a of the X-Y stage l.
At the same time, the support frame 3 is lowered. Thereby, the light transmitting/receiving ferrule 11 is abutted against the butt end face 4b of the multi-fiber connector 4, and the light transmitting/receiving fiber 13 is approximately butt-connected to the first optical fiber of the plurality of optical fibers 6a, 9 whose position is to be determined.

At this time, the light transmitting/receiving ferrule 11 does not need to be in complete contact with the multi-core connector 4, and it is sufficient that it is kept constant while measuring the measurement light from a predetermined optical fiber.

In such a roughly connected state, the transmitting/receiving optical fiber 13
The intensity of the measurement light transmitted through the optical power meter 12 is measured.

In this measurement, the X-Y stage 1 is moved in any direction within the range of the first optical fiber, and the intensity of the measurement light measured by the optical power meter 12 is the maximum, that is, the transmission loss is the smallest. The current position is read on scale 2 based on the determination result by the computer 14.

Thereafter, the positions of other optical fibers 6a and 9 corresponding to the second to n-th optical fibers are determined in the same manner. Thereby, the positions of the plurality of optical fibers 6a with reference to the guide pin holes 4c, 4c of the multi-core connector 4 are determined.

It goes without saying that in measuring the intensity of the measurement light, contrary to the above embodiment, the measurement light may be input from the transmitting/receiving fiber side and received at the multi-core connector side to measure the measurement intensity. stomach.

Further, in the above embodiment, in order to measure the position of each optical fiber 6a, 9 of the multi-core connector 4, the position where the intensity of the measurement light is maximum was determined using the optical power meter 12. For example, an imaging camera is installed on the support frame 3,
Each optical fiber 6a.

By photographing the measurement light emitted from the optical fibers 6a and 9 with an imaging camera and processing these images,
You may also measure the position of.

(Effects of the Invention) As is clear from the above explanation, according to the multi-fiber connector dimension measuring method of the present invention, a single-fiber ferrule with an optical fiber attached is inserted into the pin hole of the multi-fiber connector. The position of each optical fiber and the position of the pin hole can be measured all at once without using any other method. For this reason,
It is not necessary to measure the position of the pin hole and the position of each optical fiber separately, and the excellent effect that the position of each optical fiber with respect to the pin hole can be easily determined is achieved.

[Brief explanation of drawings]

1 and 2 illustrate an embodiment of the method of the present invention. FIG. 1 is a schematic diagram of the mechanical configuration of a measurement system that implements the method of the present invention, and FIG. 2 is a diagram similar to that of FIG. FIG. 2 is a schematic connection diagram of the measurement system of FIG. ■...X-Y 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...
・Light transmitting/receiving ferrule, 12... Optical power meter, 13
...Transmitting and receiving fiber. Figure 1

Claims (2)

[Claims] (1) Multi-core connector with pin holes and multi-core fibers,
By inserting a single-core ferrule with an optical fiber attached into the pin hole and measuring the center of each optical fiber of the single-core ferrule and the multi-core fiber, the center of the pin hole and the multi-core fiber are measured. A method for measuring the dimensions of a multi-core connector, characterized by determining the positional relationship between the centers of each optical fiber. (2) The method for measuring dimensions of a multi-fiber connector according to claim 1, wherein the measuring means for measuring the center of each optical fiber is image processing using an imaging camera.