JP3214416B2 - Image processing method for multi-core tape optical fiber, relative position detection method and detection device, image acquisition device and manufacturing method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image of a multi-core optical fiber used for measuring the shape of a multi-core optical fiber in which a plurality of coated optical fibers are arranged in parallel and a common coating is applied thereon. The present invention relates to a processing method and apparatus, a relative position detection method and apparatus for each optical fiber, and a method of manufacturing a multi-core tape optical fiber.

[0002]

2. Description of the Related Art FIG. 2 is a sectional view showing an example of a multi-core tape optical fiber. In the figure, 1 is an optical fiber, 2 is a coating layer, 3 is a clad, 4 is a core, 5 is a colored layer, 6 is a common coating, 7 is a common coating surface, 8 is a multi-core tape optical fiber, 9 is a step, 10 Is the pitch. The optical fiber 1 is
As shown in FIG. 2 (B), there is an optical transmission region composed of a high-refractive-index transparent body called a core 4 in the center, and a low-refractive-index transparent reflective layer called a clad 3 around the core. Coated. A coating layer 2 for protection or the like is provided around the clad 3. Coating layer 2
Is provided with a colored layer 5 so that the individual optical fibers 1 in the multi-core tape optical fiber 8 can be identified. A plurality of such optical fibers 1 are arranged substantially in parallel, and a common coating 6 made of a transparent resin or the like is applied to form a tape-shaped multi-core tape optical fiber 8.

In such a multi-core tape optical fiber 8,
As shown in FIG. 2A, a step 9 and a pitch 10 slightly change between the optical fibers 1 that should be aligned on a straight line. The occurrence of the step 9 and the fluctuation of the pitch 10 are not preferable in terms of quality, and need to be checked at the stage of product inspection.

Conventionally, in order to measure the shape of an optical fiber in a multi-core tape optical fiber, in particular, a step 9 and a pitch 10 between the respective optical fibers 1, the multi-core tape optical fiber is cut,
The end face was visually observed with a microscope or the like. However, a physical force is applied by the cutting, and the arrangement itself is changed by the cutting itself. For this reason, the cutting results in a deviation from the actual value due to the cutting, and a variation occurs for each measurement. In addition, because of the destructive inspection of cutting, it cannot be used for inspection on a production line, and the quality of the entire product cannot be guaranteed.

In order to solve such a problem, there has been proposed a method of performing a non-contact inspection without cutting the multi-core optical fiber. For example, JP-A-2-167415 and JP-A-6-148478 disclose a technique for observing light passing through a multi-core tape optical fiber and measuring a distance between a plurality of optical fibers, a thickness of a common coating, and the like. Has been described. However, according to these techniques, even if a step occurs between the optical fibers, the image does not change, and the state of the arrangement step of the optical fibers cannot be measured.

[0006] For example, Japanese Patent Application Laid-Open No. 6-148487 discloses a technique of irradiating a multi-core tape optical fiber with light, measuring the amount of reflected light from the multi-core tape optical fiber, and detecting the misalignment of each optical fiber. Is described. However, in the method described in this document, measurement is performed while scanning the detector in a direction substantially perpendicular to the running direction of the multi-core tape optical fiber, so that high-speed measurement is difficult. In addition, there is a problem that the common coating surface 7 is easily affected by specularly reflected light, and furthermore, it is not possible to correct the variation in the amount of reflected light due to the variation in the thickness of the common coating 6.

FIG. 3 is a schematic configuration diagram showing an example of a conventional multi-core tape optical fiber shape measuring device. In the figure, 11
Denotes an imaging camera, 12 denotes slit light, and 13 and 14 denote reflected light. Slit light 1 for multi-core tape optical fiber 8
2 and irradiates the reflected light from the optical fiber 1 with the imaging camera 1
1 is used for imaging. The slit light 12 is applied, for example, so as to substantially cross the multi-core tape optical fiber 8.
Since the common coating 6 of the multicore tape optical fiber 8 is transparent as described above, the slit light 12 reaches the surface of each optical fiber 1. Then, the reflected light 13 (scattered light) on the colored layer 5 of each optical fiber 1 is received by the imaging camera 11.

FIG. 4 is an explanatory diagram of the relationship between incident light and reflected light in a multi-core tape optical fiber. In the figure, 21, 22
Is reflected light. When the multi-core tape optical fiber 8 is irradiated with the slit light 12 at the incident angle θ1, the slit light 12 is refracted when entering the common coating 6, and travels through the common coating 6 at the output angle θ1 ′.
Then, the light is irregularly reflected on the surface of the optical fiber 1. The reflected light 21 which has been irregularly reflected travels through the common coating 6 again, reaches the common coating surface 7 at an incident angle θ2 ′, and is emitted outside at an emission angle θ2.

Now, the optical fiber 1-1 and the optical fiber 1-
2, a reflected light 21 is emitted from the surface of the optical fiber 1-1, and a reflected light 22 is emitted from the surface of the optical fiber 1-2.
Are emitted to different positions by a distance L. At this time,
The relationship between the distance D of the step 9 and the distance L of the reflected light 21 and the reflected light 22 is as follows: D = L · (cos θ1′−cos θ2 ′) / sin (θ1 ′ + θ2 ′)
· Cos θ2 θ1 '= sin ^-1 (n1 · sin θ1 / n2) θ2' = sin ^-1 (n1 · sinθ2 / n2) Here, θ1 is the incident angle of the slit light 12, θ2 is the light receiving angle, n1 is the refractive index of air, and n2 is the refractive index of the common coating 6. The distance L is determined from the image captured by the imaging camera 11, and the distance D of the step 9 between the optical fibers 1 can be determined using the above relationship.

FIG. 5 is an explanatory diagram showing the relationship between incident light and reflected light when the common coating has irregularities in the multi-core tape optical fiber. In the figure, 23 is a concave portion, and 24 is reflected light. As described above, the step 9 between the optical fibers 1 can be obtained from the image captured by the imaging camera 11, but this is limited to the case where the common coating surface 7 is flat.
If there is unevenness on the common coating surface 7, the position where the slit light 12 enters the common coating 6 is different, so that the position of the reflected light is also different. For example, when the concave portion 23 having the depth B is present on the common coating surface 7 on the upper part of the optical fiber 1-2, an optical path shown by a broken line in FIG. 5 is obtained, and the reflected light 22 and the concave portion 23 when there is no concave portion 23 are present. In this case, there is a difference of only the distance M from the reflected light 24. The distance M is given by: M = B · （sin (θ2−θ2 ′) / cosθ2 ′ + (tan θ1
− Tanθ1 ') · cosθ2｝. As described above, even if there is no arrangement step 9 of the optical fiber 1 due to the unevenness of the common coating surface 7, an error M may occur. Conversely, even if the step 9 occurs, it may be canceled out by the unevenness of the common coating surface 7, and it may appear that there is no step. Therefore, the position and shape of the optical fiber 1 cannot be accurately measured.

In order to perform an accurate measurement, the shape of the common coating surface 7 only needs to be known. As one method for that purpose, there is a method of utilizing specular reflection light of the slit light 12 on the common coating surface 7. FIG. 6 is an explanatory diagram in the case of receiving the specularly reflected light on the common coating surface in the multi-core tape optical fiber. The slit light 12 is reflected by the common coating surface 7 at a reflection angle equal to the angle of incidence on the common coating surface 7. What is necessary is just to arrange the imaging camera 11 so that this regular reflection light 14 can be received.

At this time, as shown in FIGS. 3 and 6,
The irregularly reflected light 13 from each optical fiber 1 can be received at the same time. However, the regular reflection light 14 is very strong, and the regular reflection light 1
It is difficult to obtain an image of the reflected light 13 from the optical fiber 1 from the image including the image 4.

[0013]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned circumstances, and has a simple device configuration in which a shape such as a step or a pitch between optical fibers in a multi-core tape optical fiber is made non-contact. In addition to providing an image processing method and an image acquisition device for a multi-core tape optical fiber that can be accurately inspected by using a method, and a relative position detection method and device for each optical fiber, control is performed based on such an inspection result. It is an object of the present invention to provide a method for manufacturing a multi-core tape optical fiber for manufacturing a high-quality multi-core tape optical fiber. In addition, in a multi-core tape optical fiber with a thin resin coating with a common coating, a multi-core tape optical fiber that can accurately and non-contact inspect the shape of steps or pitch between each optical fiber in the multi-core tape optical fiber The present invention provides an image processing method and an image acquisition device, and a method and an apparatus for detecting the relative position of each optical fiber, and performs control based on such inspection results to manufacture a high-quality multicore tape optical fiber. It is an object of the present invention to provide a method for manufacturing a core tape optical fiber.

[0014]

According to a first aspect of the present invention, there is provided a multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and a common coating is applied thereon. A slit light having a thickness larger than the width of the optical fiber and having a thickness sufficiently smaller than the thickness of the multi-core tape optical fiber is formed on the surface of the multi-core tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the multi-core tape optical fiber. In the image processing method of a multi-core tape optical fiber for acquiring and processing an image of the reflected light, the reflected light amount from the surface of the coating of each of the optical fibers and the reflected light amount from the surface of the common coating are determined. The amount of light reflected from the surface of the common coating is adjusted so as to be reduced to such an extent that it can be observed in the same image. Gets the reflected light from the surface of the coating bar and the reflected light from the common coating of the surface as the same image, is characterized in that process.

According to a second aspect of the present invention, there is provided the image processing method for a multi-core tape optical fiber according to the first aspect, wherein an image polarized in a direction in which the amount of reflected light from the surface of the common coating is reduced is acquired. It is characterized in that it is processed.

According to a third aspect of the present invention, in the image processing method of the multi-core tape optical fiber according to the first aspect, the angle of reflection of the light reflected from the surface of the common coating is the Brewster angle. It is characterized in that the incident angle of the slit light is set.

According to a fourth aspect of the present invention, in the image processing method of the multi-core tape optical fiber according to the second or third aspect, the slit light is directed in a direction in which the amount of reflected light from the surface of the common coating decreases. It is characterized by being polarized.

According to a fifth aspect of the present invention, in the image processing method of the multi-core tape optical fiber according to the first aspect, the numerical aperture of the reflected light from the surface of the common coating is equal to the incident light of the slit light. It is characterized in that an image is acquired in a state where the numerical aperture is large.

According to a sixth aspect of the present invention, there is provided a multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and a common coating is applied thereon, and the width is larger than the width of the multi-core tape optical fiber. The slit light whose thickness is sufficiently smaller than the thickness of the multi-core tape optical fiber is incident on the surface of the multi-core tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the multi-core tape optical fiber, and the reflected light In the image processing method for a multi-core tape optical fiber for acquiring and processing an image, an image in which the amount of light reflected from the surface of the coating of each of the optical fibers is sufficiently large with respect to the amount of light reflected from the surface of the common coating. And an image in which the amount of light reflected from the surface of the common coating is sufficiently large with respect to the amount of light reflected from the surface of the coating of the optical fiber. And acquiring and processing two images with a second image at an angle position. The invention according to claim 7 is directed to the multi-core tape optical fiber according to claim 6. In the image processing method, the first image is an image adjusted so as to reduce the amount of reflected light from the surface of the common coating.

According to an eighth aspect of the present invention, in the image processing method of the multi-core tape optical fiber according to the first or seventh aspect, the slit light has a spectrum in a wide wavelength range. Is what you do.

According to a ninth aspect of the present invention, there is provided a multi-core optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel, and a common coating is applied thereon. In the optical fiber relative position detecting method of a multi-core tape optical fiber for detecting a relative position, the slit light having a width larger than the width of the multi-core tape optical fiber and having a thickness sufficiently smaller than the thickness of the multi-core tape optical fiber is transmitted to the multi-core tape. Incident on the surface of the multicore tape optical fiber at a predetermined angle of incidence with respect to the longitudinal direction of the tape optical fiber,
The amount of reflected light from the surface of the common coating is adjusted such that the amount of reflected light from the surface of the coating of each of the optical fibers and the amount of reflected light from the surface of the common coating can be observed in the same image. From the angular position at which the reflected light from the surface of the common coating can be obtained, the reflected light from the surface of the coating and the reflected light from the surface of the common coating of the individual optical fibers are obtained as the same image and obtained. The relative position of each of the optical fibers from the surface of the common coating is calculated from an image.

According to a tenth aspect of the present invention, there is provided a multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and a common coating is applied on the plurality of coated optical fibers. In an optical fiber relative position detection method of a multi-core tape optical fiber for detecting a relative position,
The slit light whose width is larger than the width of the multi-core tape optical fiber and whose thickness is sufficiently smaller than the thickness of the multi-core tape optical fiber is formed at a predetermined incident angle with respect to the longitudinal direction of the multi-core tape optical fiber. A first angle position at which an image that is incident on the surface of the tape optical fiber and can acquire an image in which the amount of light reflected from the surface of the coating of each of the optical fibers is sufficiently large with respect to the amount of light reflected from the surface of the common coating. Acquiring two images: an image and a second image at an angular position at which an image in which the amount of light reflected from the surface of the common coating is sufficiently large with respect to the amount of light reflected from the surface of the coating of the optical fiber can be obtained. And calculating the relative position of each of the optical fibers from the surface of the common coating from the acquired image, wherein the invention according to claim 11,
The method according to claim 10, wherein the first image is an image adjusted so as to reduce the amount of reflected light from the surface of the common coating. Is what you do.

According to a twelfth aspect of the present invention, there is provided a method for manufacturing a multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and a common coating is applied thereon. Slit light having a thickness larger than the width and sufficiently smaller than the thickness of the multi-core tape optical fiber is incident on the surface of the multi-core tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the multi-core tape optical fiber. The optical fiber is adjusted so that the amount of reflected light from the surface of the common coating and the amount of reflected light from the surface of the common coating can be observed in the same image so as to reduce the amount of reflected light from the surface of the common coating. From the angular position where the reflected light from the surface of the optical fiber can be obtained, the reflected light from the surface of the coating of the individual optical fibers and the reflected light from the surface of the common coating are the same image. Obtain, calculate the relative position of each of the optical fibers from the surface of the common coating from the obtained image, and change the resin coating condition of the multi-core tape optical fiber when the relative position exceeds a predetermined position range. And adjusting the relative positions of the individual optical fibers from the surface of the common coating.

According to a thirteenth aspect of the present invention, there is provided a method for manufacturing a multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and a common coating is applied thereon. Slit light having a thickness larger than the width and sufficiently smaller than the thickness of the multi-core tape optical fiber is incident on the surface of the multi-core tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the multi-core tape optical fiber. A first image at an angular position where an image in which the amount of light reflected from the surface of the optical fiber from the surface of the coating is sufficiently large with respect to the amount of light reflected from the surface of the common coating, and a reflection from the surface of the common coating; Two images at an angular position where an image whose light amount is sufficiently large with respect to the amount of light reflected from the surface of the coating of the optical fiber and the second image at an angular position can be obtained. The relative position of each of the optical fibers from the surface of the common coating is calculated, and when the relative position exceeds a predetermined position range, the resin application condition of the multi-core optical fiber is changed to change the resin coating condition of each of the optical fibers. The relative position from the surface of the common coating is adjusted, and the invention according to claim 14 is the method of manufacturing a multicore tape optical fiber according to claim 13, wherein The image is an image adjusted so as to reduce the amount of reflected light from the surface of the common coating.

According to a fifteenth aspect of the present invention, there is provided a method for manufacturing a multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and a common coating is applied thereon. Slit light having a thickness larger than the width and sufficiently smaller than the thickness of the multi-core tape optical fiber is incident on the surface of the multi-core tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the multi-core tape optical fiber. The optical fiber is adjusted so that the amount of reflected light from the surface of the common coating and the amount of reflected light from the surface of the common coating can be observed in the same image so as to reduce the amount of reflected light from the surface of the common coating. From the angular position where the reflected light from the surface of the optical fiber can be obtained, the reflected light from the surface of the coating of the individual optical fibers and the reflected light from the surface of the common coating are the same image. Acquiring, calculating an average thickness of the common coating from the obtained image, and controlling resin application conditions of the common coating so that the common coating has a predetermined thickness based on the average thickness. It is assumed that.

According to a sixteenth aspect of the present invention, there is provided a method for manufacturing a multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and a common coating is applied thereon. Slit light having a thickness larger than the width and sufficiently smaller than the thickness of the multi-core tape optical fiber is incident on the surface of the multi-core tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the multi-core tape optical fiber. A first image at an angular position where an image in which the amount of light reflected from the surface of the optical fiber from the surface of the coating is sufficiently large with respect to the amount of light reflected from the surface of the common coating, and a reflection from the surface of the common coating; Two images at an angular position where an image whose light amount is sufficiently large with respect to the amount of light reflected from the surface of the coating of the optical fiber and the second image at an angular position can be obtained. Calculating an average thickness of the common coating, and controlling a resin application condition of the common coating so that the common coating has a predetermined thickness based on the average thickness. The invention described in Item 17 is:
17. The method according to claim 16, wherein the first image is an image adjusted so as to reduce the amount of light reflected from the surface of the common coating. .

The invention according to claim 18 is an image acquisition apparatus for a multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and an image of the multi-core tape optical fiber having a common coating thereon is obtained. In the above, the slit light having a width larger than the width of the multi-core tape optical fiber and having a thickness sufficiently smaller than the thickness of the multi-core tape optical fiber is formed at a predetermined incident angle with respect to the longitudinal direction of the optical fiber. Light projecting means for entering the fiber surface, and the amount of reflected light from the surface of the coating and the amount of light reflected from the surface of the common coating of each of the optical fibers can be observed in the same image from the surface of the common coating. A polarizing means having a plane of polarization set in a direction to reduce the amount of reflected light, and the reflected light from the surface of the coating of each of the optical fibers and the surface of the common coating via the polarizing means. It is characterized in that it has an imaging means arranged in angular positions that can be incorporated as the same images and the reflected light.

According to a nineteenth aspect of the present invention, there is provided an image acquisition apparatus for a multi-core tape optical fiber for arranging a plurality of coated optical fibers substantially in parallel and obtaining an image of the multi-core tape optical fiber having a common coating thereon. In the above, the slit light having a width larger than the width of the multi-core tape optical fiber and having a thickness sufficiently smaller than the thickness of the multi-core tape optical fiber is formed at a predetermined incident angle with respect to the longitudinal direction of the optical fiber. A light projecting means for entering the surface of the fiber, a polarizing means having a polarization plane set in a direction to reduce the amount of reflected light from the surface of the coating of the optical fiber, and the individual optical fibers through the polarizing means. A first imaging unit disposed at an angular position where an image in which the amount of light reflected from the surface of the coating is sufficiently larger than the amount of light reflected from the surface of the common coating can be obtained; And a second imaging unit disposed at an angular position where an image in which the amount of reflected light from the surface of the optical fiber is sufficiently larger than the amount of reflected light from the surface of the coating of the optical fiber can be obtained. .

According to a twentieth aspect of the present invention, there is provided an image acquisition apparatus for a multi-core optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and an image of the multi-core optical fiber having a common coating thereon is obtained. In the reflection of the reflected light from the surface of the common coating with respect to the longitudinal direction of the optical fiber, the slit light whose width is larger than the width of the multi-core tape optical fiber and whose thickness is sufficiently smaller than the thickness of the multi-core tape optical fiber Light projecting means for entering the surface of the multi-core tape optical fiber at an angle of incidence at which the angle becomes a Brewster angle; light reflected from the surface of the coating of each of the optical fibers and light reflected from the surface of the common coating; And an imaging means for capturing the same as the same image or two images.

According to a twenty-first aspect of the present invention, in the image acquisition device for a multi-core tape optical fiber according to any one of the eighteenth to twentieth aspects, the light projecting means reflects light from a surface of the common coating. A light source-side polarizing means for polarizing the slit light in a direction in which the light amount decreases is provided.

According to a twenty-second aspect of the present invention, there is provided an image acquisition apparatus for a multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and an image of a multi-core tape optical fiber having a common coating thereon is obtained. In, the slit light having a width larger than the width of the multi-core tape optical fiber and having a thickness sufficiently smaller than the thickness of the multi-core tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the optical fiber. Light projecting means for entering the surface, and reflected light from the surface of the common coating such that the amount of light reflected from the surface of the coating of each of the optical fibers and the amount of light reflected from the surface of the common coating can be observed in the same image. Numerical aperture adjusting means for setting the numerical aperture of the slit light to be larger than the numerical aperture of the incident light of the slit light by the light emitting means, and individual numerical apertures through the numerical aperture adjusting means It is characterized in that it has an imaging means arranged in angular positions taken in as the same image an image of the reflected light from the reflection light and the common coating of the surface from the surface of the coating of the serial optical fiber.

According to a twenty-third aspect of the present invention, in the image acquisition device for a multi-core tape optical fiber according to any one of the eighteenth to twenty-second aspects, the light projecting means is provided on a surface of the multi-core tape optical fiber. The slit light to be incident has a spectrum in a wide wavelength range.

According to a twenty-fourth aspect of the present invention, in a multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and a common coating is applied thereon, each of the individual optical fibers is separated from the surface of the common coating. In the optical fiber relative position detection device of the multi-core tape optical fiber for detecting the relative position,
The slit light whose width is larger than the width of the multi-core tape optical fiber and whose thickness is sufficiently smaller than the thickness of the multi-core tape optical fiber is formed on the surface of the multi-core tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the optical fiber. Light-projecting means for making incident, image-capturing means for capturing images of reflected light from the surface of the coating of each of the optical fibers and light reflected from the surface of the common coating as the same image or two images, and A relative position calculating means for calculating a relative position of each of the optical fibers from the surface of the common coating from the captured image.

[0034]

FIG. 1 is a block diagram showing an embodiment of the present invention. In the figure, 31 is a light projecting unit, 32 is a light receiving unit, 33 is a base, 34 is an opening angle adjusting mechanism, 35 is a guide roller, 36 is a measurement surface, 41 is a light source, 42 is a cylindrical lens, 43 is a polarizing filter, 44 Is a slit, 45 is an opening angle adjusting mechanism, 51 is a polarizing filter, 5
2 is a camera. The multi-core tape optical fiber 8 is fed according to a guide roller 35. The light projecting unit 31 irradiates the measuring surface 36 of the multi-core tape optical fiber 8 with the slit light, captures the reflected light with the light receiving unit 32, and acquires the image as an image. The angle of the light receiving unit 32 is adjusted by the opening angle adjusting mechanism 34 so that the slit light reflected regularly on the measurement surface 36 can be received. Of course, this angle is
6 is constant unless the angle is changed, the opening angle adjusting mechanism 34 need not be provided. In this example, the light projecting unit 31 and the light receiving unit 32 are provided on the common base 33, but may be separately provided.

The light projecting section 31 has a light source 41, a cylindrical lens 42, a polarizing filter 43, a slit 44, an opening angle adjusting mechanism 45 and the like. The light source 41 preferably has a spectrum in a wide wavelength range. FIG. 7 is an explanatory diagram of a difference between acquired images depending on a light projection light source. Figure 2 above
As shown in (B), each optical fiber 1 in the multi-core tape optical fiber 8 is provided with a coloring layer 5. The color of the coloring layer 5 is different for each optical fiber 1. Therefore, when a light source having a specific wavelength is used, sufficient reflection light may not be obtained for an optical fiber of a specific color. In the image shown in FIG. 7A, the optical fiber indicated by the arrow does not have a sufficient amount of reflected light, and is faint or missing. The arrow on the left side shows a faint state with a broken line, and the arrow on the right side shows a state with a break. By using the light source 41 having a spectrum in a wide wavelength range, a sufficient amount of reflected light can be obtained and substantially uniform luminance can be obtained regardless of the color of the colored layer 5 of each optical fiber 1. Therefore, as shown in FIG. 7B, good images of all the optical fibers 1 can be obtained.

The cylindrical lens 42 condenses the light from the light source 41 linearly and increases the amount of light illuminating the measurement surface 36. Further, the slit 44 limits the light from the light source 41 to a linear shape having a predetermined width, and defines an irradiation area on the measurement surface 36. The polarization filter 43 transmits only light of a specific polarization plane out of the light from the light source 41.

On the other hand, the light receiving section 32 has a polarizing filter 51, a camera 52, an opening angle adjusting mechanism 34 and the like. The polarizing filter 51 is configured to reflect light incident on the light receiving unit 32 from the common coating surface 7 of the multi-core tape optical fiber 8, and
Of the reflected light scattered by the colored layer 5 of each optical fiber 1,
Only reflected light having a predetermined polarization plane is transmitted. The camera 52 can be composed of, for example, a CCD camera or the like, and receives the reflected light that has entered through the polarization filter 51 and outputs it as an image signal. At this time, both images of the reflected light from the common coating surface 7 of the multi-core tape optical fiber 8 and the reflected light scattered by the colored layer 5 of each optical fiber 1 are acquired as one image. In addition, each optical fiber 1
Since the reflected light of the colored layer 5 is scattered light, the spread angle of the reflection is widened. Therefore, by setting the numerical aperture of the light receiving section 32 larger than the numerical aperture of the light projecting section 31, more reflected light can be received.

Next, the relationship between the polarizing filter 43 of the light projecting section 31 and the polarizing filter 51 of the light receiving section 32 will be described.
FIG. 8 is an explanatory diagram of a configuration for suppressing specular reflection light by two polarizing filters according to an embodiment of the present invention. The surface of the multi-core tape optical fiber 8, ie, the common coated surface 7
In the reflection of light at, the polarization direction is maintained. In the light reflection on the colored layer 5 of each optical fiber 1, the polarization direction is random. Utilizing this property, for example, the slit light is polarized in a certain polarization direction by the polarization filter 43, and the polarization direction of the polarization filter 51 is changed to the polarization filter 43.
If the direction is perpendicular to the polarization direction, the extinction ratio increases, and the light reflected from the common coating surface 7 cannot pass through the polarization filter 51. Therefore, the amount of reflected light from the common coating surface 7 can be suppressed. Further, the reflected light from the colored layer 5 of each optical fiber 1 sufficiently passes through the polarization filter 51 because the polarization direction is random. By suppressing the amount of reflected light from the common coating surface 7 in this manner,
In the camera 52, the image of the specularly reflected light from the common coating surface 7 and the image of the reflected light from the colored layer 5 of each optical fiber 1 are
It can be obtained as the same image.

Further, the polarization direction of the polarization filter 43 on the light projecting section 31 side is set to, for example, only p-polarized light composed of components included in the incident surface, and the incident angle of the slit light is set to the Brewster angle. The common coating surface 7
Can suppress specular reflection at In general, when the incident angle is a Brewster angle, a vibration component parallel to the incident surface has a property of being completely transmitted. By setting the slit light to only the p-polarized light by the polarizing filter 43, most of the slit light passes through the common coating surface 7 and proceeds into the common coating 6. Therefore, for example, the camera 5 can be provided without providing the polarizing filter 51.
2, the amount of specular reflection on the common coating surface 7 is suppressed, and the image of the specular reflection light from the common coating surface 7 and each optical fiber 1
The image of the reflected light from the colored layer 5 can be obtained as the same image.

FIG. 9 is an explanatory diagram of a specific example of an image processing method according to an embodiment of the present invention. In the figure, 61 is a regular reflection image from the common coating surface, 62 is a reflection image from the optical fiber, 63 is a scanning line, and 64 and 65 are peaks. As described above, the regular reflection image 61 from the common coating surface 7 and the reflection image 62 from each optical fiber 1 are obtained as the same image by the camera 52 as shown in FIG. At this time, the amount of specular reflection from the common coating surface 7 is suppressed to an extent that can be distinguished from the amount of reflection from each optical fiber 1.

The observation image is scanned from the regular reflection image 61 from the common coating surface 7 toward the reflection image 62 from each optical fiber 1 to check the luminance distribution. The graph shown in FIG. 9B shows the luminance distribution on the scanning line 63 in FIG. 9A. As shown in FIG. 9B, the luminance distribution is a regular reflection image 6 from the common coating surface 7.
1 and the reflection image 62 from each optical fiber 1
Have peaks 64 and 65 at the position where. The positions of the peaks 64 and 65 are obtained for each scanning line.

When a luminance distribution as shown in FIG. 9B is obtained, it is easy to be affected by noise from only one observation image. Therefore, for example, the luminance distribution of the scan line at the same position may be averaged from a plurality of observation images to obtain the luminance distribution.

The peaks 64, 6 thus determined
From the position 5, the relative position of the surface of each optical fiber 1 when the common coating surface 7 is flattened according to the relationship shown in FIG. 4 can be obtained. However, this relative position includes an error due to the thickness of the common coating 6 as shown in FIG. The thickness of the common coating 6 can be easily obtained from the difference between the positions of the peak 64 and the peak 65. The relative position of the surface of each optical fiber 1 may be corrected based on the obtained thickness of the common coating 6.

When the position of the common coating surface 7 obtained in this way and the position of the surface of the optical fiber 1 are plotted on a two-dimensional plane, they are indicated by crosses in FIG. 9C. . The position of the upper surface of the optical fiber 1 can be obtained by approximating the position of the surface of the optical fiber 1 obtained in each scanning line by a curve and obtaining the maximum point. Thus, the relative position of each optical fiber in the multi-core tape optical fiber can be accurately detected.

Further, by linearly approximating the position of the common coating surface 7 obtained in each scanning line and calculating the distance to the position of the common coating surface 7 at the upper end position of the optical fiber 1, the thickness of the common coating 6 can be obtained. Can be obtained. Furthermore, the pitch between the optical fibers 1 can be known by calculating the upper end position of each optical fiber 1 and calculating the distance between the adjacent optical fibers 1. In this way, regardless of the thickness of the common coating 6, the arrangement step, pitch, and the like of each optical fiber 1 can be obtained.

Based on the data such as the relative position of the optical fiber 1 and the thickness of the common coating 6, the quality of the multi-core optical fiber 8 can be inspected. Further, the quality of the multi-core tape optical fiber 8 can be improved by feeding these data back to the manufacturing process of the multi-core tape optical fiber 8. For example, if the relative position of the optical fiber 1 from the common coating surface 7 exceeds a predetermined position range, the optical fiber 1 may be deviated, etc. It is conceivable to reduce such factors. Alternatively, the average of the thickness of the common coating 6 at the upper end of each optical fiber 1 is calculated, and the application condition of the resin for forming the common coating 6 can be controlled so that the thickness becomes substantially a predetermined thickness. For example, when the common coating 6 becomes thinner, if the amount of resin per unit area supplied as the common coating 6 is increased, the common coating 6 becomes thicker and a predetermined quality can be maintained.

As described above, in the case of the light cutting using the slit light, when the reflected light from the common coated surface of the multi-core tape optical fiber and the surface of the coated optical fiber is observed in one image, Due to the large amount of reflected light, the brightness of the surface portion of the optical fiber coating cannot be sufficiently obtained, making observation difficult. Therefore, by using a polarizing filter to suppress the amount of light reflected from the common coating surface, the brightness of the light reflected from the common coating surface and the brightness of the light reflected from the surface of the optical fiber coating are almost the same. The reflected light from the surface of the common coating and the reflected light from the surface of the optical fiber coating are simultaneously observed in one image as shown in FIG. 10A, and the position can be measured. As described above, when the resin thickness of the common coating has a certain thickness, the image of the light reflected from the surface of the common coating and the image of the light reflected from the surface of the optical fiber coating are observed at distant positions. 10 (A), the distribution of the brightness (brightness) in the leftmost line among the lines shown by the dotted lines is the peak of the reflected light from the surface of the common coating as shown in FIG. 10 (B). And the peak of the reflected light on the surface of the coating of the optical fiber appears slightly lower at a position distant from the reflected light from the surface of the common coating.

However, in the case of a multi-core tape optical fiber having a small resin thickness, the reflected light from the surface of the common coating and the surface of the coating of the optical fiber are observed very close, and as shown in FIG. The image of the reflected light from the surface of the common coating and the image of the reflected light from the surface of the optical fiber coating are observed at close positions, and the position of the vertex of the surface of the optical fiber coating to be detected and the position of the vertex It is difficult to accurately measure the position of the common coating surface. FIG.
FIG. 10D shows the distribution of luminance (brightness) in the leftmost line of the dotted lines in FIG.
As shown in (1), it is difficult to separate the peak of the reflected light from the surface of the common coating from the peak of the reflected light from the surface of the optical fiber coating.

FIG. 11 is a block diagram showing an example of an embodiment of the present invention suitable for a multi-core tape optical fiber having a thin resin with a common coating. The same parts as those in FIG. 1 are denoted by the same reference numerals and description thereof will be omitted. Although two light receiving units are used, the same reference numerals as those in FIG. 1 are denoted by "a" and "b", and the description thereof is omitted.

The light projecting section 31 irradiates the slit light to the measurement surface 36 of the multi-core tape optical fiber 8. The reflected light from the common coating surface of the multi-core tape optical fiber 8 is slit light projected at an angle such that there is a large amount of regular reflection light, so that this light can be received and the reflected light from the surface of the optical fiber coating can be reflected. The light receiving section 32a is arranged at an angular position that is sufficiently small. Even when θ1 and θ2 are set to the same angle position, the amount of light reflected from the surface of the optical fiber coating is smaller than the amount of light reflected from the surface of the common coating. It can be observed separately from the image of the reflected light on the surface of the optical fiber coating. The polarizing filter 51a may not be provided, but if this is provided and its angle is adjusted so that the most reflected light from the surface of the common coating can be received, the reflected light from the surface of the coating of the optical fiber can be obtained. The amount of light incident on the camera 52a can be reduced and the reflected light can be easily acquired from the surface of the common coating. In this manner, the image of the reflected light from the surface of the common coating can be acquired by the camera 52a.

The light receiving section 32b is located at a position where it is less affected by the reflected light from the surface of the common coating and at an angular position where it can receive the reflected light from the surface of the optical fiber coating. Since the reflected light from the common coating surface of the multi-core tape optical fiber 8 has a large amount of regular reflection light, for example, the light receiving portion 32b is arranged so as to be at an angular position θ3 smaller than θ2, and from the surface of the coating of the optical fiber. May be received. However, due to the unevenness of the surface of the common coating, reflected light from the surface of the common coating may be seen in the vicinity of an observation image of the surface of the optical fiber coating as shown in FIG. , Which becomes noise at the time of image processing, and becomes a measurement error or an error at the time of calculating a circular term vertex. To eliminate this noise, the polarization filter 51b is used to adjust its angle to reduce the light reflected from the common coating surface, thereby reducing the unevenness of the common coating surface itself, as shown in FIG. Noise due to the noise can be reduced.

In a specific example of the angular positions of the light projecting unit 31 and the light receiving units 32a and 32b, the opening angle θ1 of the light projecting unit 31 is set to 6
0 °, the opening angle θ2 of the light receiving portion 32a for observing the surface of the common coating was 60 °, and the opening angle θ3 of the light receiving portion 32b for observing the surface of the optical fiber coating was 30 °.

The position measurement from the two images observed from two directions by the two light receiving units is basically performed at the position of the core wire detected by the image in the same manner as the method performed on one image observed from one direction. On the other hand, a calculation process may be performed using the projection angle, the reception angle, and the refractive index of the resin as correction data.

In the embodiment described with reference to FIG.
The relative position of each optical fiber can be detected from the acquired image, and control can be performed based on such an inspection result, so that a high-quality multicore tape optical fiber can be manufactured.

[0055]

As is apparent from the above description, according to the first aspect of the present invention, the shape of the multi-core tape optical fiber can be measured in a non-contact and non-destructive manner. At this time, the relative position in the depth direction and the pitch of the optical fiber can be accurately obtained from the images of the reflected light from the common coating surface and the reflected light from the colored layer of the optical fiber. Since the image of the reflected light from the surface of the coating and the light reflected from the surface of the coating of the optical fiber can be acquired as the same image, the apparatus can be downsized and the cost can be reduced.

According to the sixth aspect of the present invention, even if the resin thickness of the common coating is small, the image of the reflected light on the surface of the common coating and the image of the reflected light on the surface of the coating of the optical fiber can be obtained from the images from two directions. , The relative position in the depth direction and the pitch of the optical fibers can be accurately obtained.

According to the invention described in claims 2, 7, 11, 14, 17, 18 and 19, an image polarized in a direction in which the amount of reflected light from the surface of the common coating decreases is processed. Thereby, the image of the reflected light from the surface of the common coating and the image of the reflected light from the surface of the coating of the optical fiber can be distinguished, and the relative position of the optical fiber can be easily detected. Further, when an image of the reflected light on the surface of the optical fiber coating is obtained at an angular position where the reflected light from the surface of the optical fiber coating is sufficiently suppressed, the noise of the reflected light due to the unevenness of the surface of the common coating is reduced. be able to.

According to the third and twentieth aspects of the present invention, the incident angle of the slit light is set such that the angle of reflection of the reflected light from the surface of the common coating becomes the Brewster angle. The amount of light reflected from the optical fiber can be reduced, and the image of the light reflected from the surface of the common coating and the image of the light reflected from the surface of the coating of the optical fiber can be distinguished as in the third aspect. Further, when an image of the reflected light on the surface of the optical fiber coating is obtained at an angular position where the reflected light from the surface of the optical fiber coating is sufficiently suppressed, the noise of the reflected light due to the unevenness of the surface of the common coating is reduced. be able to.

According to the fourth and twenty-first aspects of the invention, the slit light is polarized in a direction in which the amount of reflected light from the surface of the common coating decreases, thereby further reducing the amount of light reflected from the surface of the common coating. This makes it easier to distinguish between the image of the reflected light from the common coating surface and the image of the light reflected from the surface of the optical fiber coating.

According to the fifth and twenty-second aspects of the present invention, an image is obtained in a state where the numerical aperture of the reflected light from the surface of the common coating is larger than the numerical aperture of the incident light of the slit light. More reflected light (scattered light) components from the surface of the optical fiber coating can be received.

According to the eighth and twenty-third aspects of the present invention, by using light having a spectrum in a wide wavelength range as the slit light, reflected light can be observed on the surface of the coating of each optical fiber regardless of the color. can do.

According to the ninth, tenth and twenty-fourth aspects, it is possible to calculate the relative position of each of the optical fibers from the surface of the common coating from the acquired image.

According to the twelfth, thirteenth, fifteenth, and sixteenth aspects of the present invention, the relative positions of the individual optical fibers obtained in this manner are predetermined based on the relative positions from the surface of the common coating. By changing the resin coating conditions of the multi-core optical fiber when the position range is exceeded and adjusting the relative position of the individual optical fibers from the surface of the common coating, the quality of the multi-core optical fiber is always constant. Can be kept. According to the twelfth aspect of the invention, based on the average thickness of the common coating obtained in the same manner, the resin application conditions of the common coating are controlled so that the common coating has a predetermined thickness. Accordingly, there is an effect that a multi-core tape optical fiber having a constant quality can be manufactured.

[Brief description of the drawings]

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

FIG. 2 is a cross-sectional view illustrating an example of a multi-core tape optical fiber.

FIG. 3 is a schematic configuration diagram showing an example of a conventional multi-core tape optical fiber shape measuring device.

FIG. 4 is an explanatory diagram of a relationship between incident light and reflected light in a multi-core tape optical fiber.

FIG. 5 is an explanatory diagram of a relationship between incident light and reflected light when a common coating has irregularities in a multi-core tape optical fiber.

FIG. 6 is an explanatory diagram in the case of receiving specularly reflected light on a common coating surface in a multi-core tape optical fiber.

FIG. 7 is an explanatory diagram of a difference in an acquired image depending on a light projection light source.

FIG. 8 is an explanatory diagram of a configuration for suppressing specular reflection light by two polarizing filters according to an embodiment of the present invention.

FIG. 9 is an explanatory diagram of a specific example of an image processing method according to an embodiment of the present invention.

FIG. 10 is an explanatory diagram of observation images of a common coating surface and a surface of an optical fiber coating.

FIG. 11 is a configuration diagram showing an example of an embodiment of the present invention suitable for a multi-core tape optical fiber having a thin resin with a common coating.

FIG. 12 is an explanatory diagram of an observation image of the surface of the optical fiber coating when the common coating surface has irregularities.

[Explanation of symbols]

1: optical fiber, 2: coating layer, 3: clad,
4 core, 5 colored layer, 6 common coating, 7 common coating surface, 8 multi-core tape optical fiber, 9 steps, 10 pitch, 11 imaging camera, 12 slit light, 13, 14
... reflected light, 21, 22 ... reflected light, 23 ... concave part, 24 ... reflected light, 31 ... light emitting part, 32, 32a, 32b ... light receiving part,
33: Base, 34: Opening angle adjusting mechanism, 35: Guide roller, 36: Measurement surface, 41: Light source, 42: Cylindrical lens, 43: Polarizing filter, 44: Slit, 4
5: Opening angle adjusting mechanism, 51, 51a, 51b: Polarizing filter, 52, 52a, 52b: Camera, 61: Regular reflection image from common coating surface, 62: Reflection image from optical fiber, 63: Scan line, 64 , 65 ... peak.

──────────────────────────────────────────────────続 き Continued on the front page (58) Fields investigated (Int. Cl. ⁷ , DB name) G01B 11/00-11/30 102 G01N 21/84-21/958 G01M 11/00-11/08 G02B 6 / 00

Claims (24)

(57) [Claims] 1. A multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and a common coating is applied thereon.
The slit light whose width is larger than the width of the multi-core tape optical fiber and whose thickness is sufficiently smaller than the thickness of the multi-core tape optical fiber is formed at a predetermined incident angle with respect to the longitudinal direction of the multi-core tape optical fiber. In the image processing method of the multi-core tape optical fiber which is incident on the surface of the tape optical fiber and acquires and processes an image of the reflected light, the amount of reflected light from the surface of the coating of each of the optical fibers and the common coating Adjusted to reduce the amount of reflected light from the surface of the common coating to the extent that the amount of reflected light from the surface can be observed in the same image, and from the angular position where the reflected light from the surface of the common coating can be acquired, An image of a multi-core tape optical fiber, wherein light reflected from the surface of the coating of the optical fiber and light reflected from the surface of the common coating are acquired as the same image and processed. Processing method. 2. The image processing method for a multi-core optical fiber according to claim 1, wherein an image polarized in a direction to reduce the amount of reflected light from the surface of the common coating is acquired and processed. 3. The multi-core optical fiber according to claim 1, wherein the angle of incidence of the slit light is set such that the angle of reflection of the light reflected from the surface of the common coating is the Brewster angle. Image processing method. 4. The image processing method for a multi-core tape optical fiber according to claim 2, wherein the slit light is polarized in a direction in which the amount of reflected light from the surface of the common coating decreases. . 5. An image according to claim 1, wherein the image is acquired in a state where the numerical aperture of the reflected light from the surface of the common coating is larger than the numerical aperture of the incident light of the slit light. Image processing method for core tape optical fiber. 6. A multi-core optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and a common coating is applied thereon.
The slit light whose width is larger than the width of the multi-core tape optical fiber and whose thickness is sufficiently smaller than the thickness of the multi-core tape optical fiber is formed at a predetermined incident angle with respect to the longitudinal direction of the multi-core tape optical fiber. In the image processing method of the multi-core tape optical fiber, which is incident on the surface of the tape optical fiber and acquires and processes an image of the reflected light, the amount of reflected light from the surface of the coating of each of the optical fibers is equal to the amount of the common coating. A first image at an angular position at which an image that is sufficiently large with respect to the amount of light reflected from the surface can be acquired, and the amount of light reflected from the surface of the common coating relative to the amount of light reflected from the surface of the coating of the optical fiber; An image processing method for a multi-core tape optical fiber, comprising: acquiring and processing two images including a second image at an angular position at which an image that becomes sufficiently large can be acquired. 7. The image processing of a multi-core optical fiber according to claim 6, wherein the first image is an image adjusted so as to reduce the amount of reflected light from the surface of the common coating. Method. 8. The image processing method according to claim 1, wherein the slit light has a spectrum in a wide wavelength range. 9. A multi-core tape for arranging a plurality of coated optical fibers substantially in parallel and detecting a relative position of each of the optical fibers from the surface of the common coating in a multi-core tape optical fiber on which a common coating is applied. In the optical fiber relative position detection method of the tape optical fiber, the slit light having a width larger than the width of the multi-core tape optical fiber and having a thickness sufficiently smaller than the thickness of the multi-core tape optical fiber in a longitudinal direction of the multi-core tape optical fiber. Incident on the surface of the multi-core tape optical fiber at a predetermined incident angle, and the amount of reflected light from the surface of the coating of each of the optical fibers and the amount of reflected light from the surface of the common coating can be observed in the same image. In order to reduce the amount of reflected light from the surface of the common coating, from the angular position from which the reflected light from the surface of the common coating can be obtained, the individual light The reflected light from the surface of the coating of the fiber and the reflected light from the surface of the common coating are acquired as the same image, and the relative positions of the individual optical fibers from the surface of the common coating are calculated from the acquired images. An optical fiber relative position detecting method for a multi-core tape optical fiber, comprising: 10. A multi-core optical fiber for arranging a plurality of coated optical fibers substantially parallel to each other and detecting a relative position of each of the optical fibers from the surface of the common coating in a multi-core tape optical fiber on which a common coating is applied. In the optical fiber relative position detecting method of the tape optical fiber, the slit light having a width larger than the width of the multi-core tape optical fiber and having a thickness sufficiently smaller than the thickness of the multi-core tape optical fiber, Incident on the surface of the multi-core tape optical fiber at a predetermined incident angle with respect to the direction, the amount of light reflected from the surface of the coating of each of the optical fibers is sufficiently large with respect to the amount of light reflected from the surface of the common coating. A first image at an angular position at which an image can be obtained, and the amount of reflected light from the surface of the common coating is relative to the amount of reflected light from the surface of the coating of the optical fiber. Acquiring two images with the second image at an angular position at which an image that becomes sufficiently large can be acquired, and calculating a relative position of each of the optical fibers from the surface of the common coating from the acquired image. Method for detecting the relative position of an optical fiber in a multi-core tape optical fiber. 11. The optical fiber according to claim 10, wherein the first image is an image adjusted so as to reduce the amount of reflected light from the surface of the common coating. Relative position detection method. 12. A method for manufacturing a multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and a common coating is applied thereon, wherein the width is larger than the width of the multi-core tape optical fiber and the thickness is larger. Slit light that is sufficiently smaller than the thickness of the core tape optical fiber is incident on the surface of the multicore tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the multicore tape optical fiber, and the coating of each of the optical fibers is formed. The amount of reflected light from the surface of the common coating is adjusted such that the amount of reflected light from the surface and the amount of reflected light from the surface of the common coating can be observed in the same image so that the amount of reflected light from the surface of the common coating is reduced. From the obtainable angular position, the reflected light from the surface of the coating of each of the optical fibers and the reflected light from the surface of the common coating are acquired as the same image, and the acquired image is Calculate the relative position of each of the optical fibers from the surface of the common coating, and when the relative position exceeds a predetermined position range, change the resin coating conditions of the multi-core tape optical fiber to change the individual optical fibers. Adjusting the relative position from the surface of the common coating to the multi-core optical fiber. 13. A method for manufacturing a multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and a common coating is applied thereon, the width being larger than the width of the multi-core tape optical fiber and the thickness being larger than the width of the multi-core tape optical fiber. Slit light that is sufficiently smaller than the thickness of the core tape optical fiber is incident on the surface of the multicore tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the multicore tape optical fiber, and the coating of each of the optical fibers is formed. A first image at an angle position at which an image in which the amount of reflected light from the surface is sufficiently large with respect to the amount of reflected light from the surface of the common coating, and the amount of reflected light from the surface of the common coating is the optical fiber. The second position at an angular position where an image that is sufficiently large with respect to the amount of reflected light from the surface of the coating can be obtained
And two images are acquired, and the relative positions of the individual optical fibers from the surface of the common coating are calculated from the acquired images, and when the relative position exceeds a predetermined position range, the multi-core tape is obtained. A method for manufacturing a multi-core tape optical fiber, comprising: changing a resin application condition of an optical fiber to adjust a relative position of each of the optical fibers from a surface of the common coating. 14. The method according to claim 13, wherein the first image is an image adjusted so as to reduce the amount of reflected light from the surface of the common coating. . 15. A method of manufacturing a multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and a common coating is applied thereon, wherein the width is larger than the width of the multi-core tape optical fiber and the thickness is larger. Slit light that is sufficiently smaller than the thickness of the core tape optical fiber is incident on the surface of the multicore tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the multicore tape optical fiber, and the coating of each of the optical fibers is formed. The amount of reflected light from the surface of the common coating is adjusted such that the amount of reflected light from the surface and the amount of reflected light from the surface of the common coating can be observed in the same image so that the amount of reflected light from the surface of the common coating is reduced. From the obtainable angular position, the reflected light from the surface of the coating of each of the optical fibers and the reflected light from the surface of the common coating are acquired as the same image, and the acquired image is Calculating the average thickness of the common coating, and controlling the resin application conditions of the common coating based on the average thickness such that the common coating has a predetermined thickness. Fiber manufacturing method. 16. A method for producing a multi-core tape optical fiber in which a plurality of coated optical fibers are arranged substantially in parallel and a common coating is applied thereon, wherein the width is larger than the width of the multi-core tape optical fiber and the thickness is larger. Slit light that is sufficiently smaller than the thickness of the core tape optical fiber is incident on the surface of the multicore tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the multicore tape optical fiber, and the coating of each of the optical fibers is formed. A first image at an angle position at which an image in which the amount of reflected light from the surface is sufficiently large with respect to the amount of reflected light from the surface of the common coating, and the amount of reflected light from the surface of the common coating is the optical fiber. The second position at an angular position where an image that is sufficiently large with respect to the amount of reflected light from the surface of the coating can be obtained
The image of the common coating is obtained, the average thickness of the common coating is calculated from the obtained image, and the resin of the common coating is formed such that the common coating has a predetermined thickness based on the average thickness. A method for producing a multi-core tape optical fiber, characterized by controlling application conditions. 17. The method according to claim 16, wherein the first image is an image adjusted so as to reduce the amount of reflected light from the surface of the common coating. . 18. A multi-core tape optical fiber image acquisition apparatus for arranging a plurality of coated optical fibers substantially in parallel and acquiring an image of a multi-core tape optical fiber having a common coating thereon. A slit light having a width larger than the width of the tape optical fiber and a thickness sufficiently smaller than the thickness of the multi-core tape optical fiber is incident on the surface of the multi-core tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the optical fiber. Optical means, in a direction to reduce the amount of reflected light from the surface of the common coating to the extent that the amount of reflected light from the surface of the coating and the amount of reflected light from the surface of the common coating of each of the optical fibers can be observed in the same image. Polarization means having a plane of polarization set, and the same image as the light reflected from the surface of the coating and the light reflected from the surface of the common coating of each of the optical fibers via the polarization means. An image acquisition apparatus for a multi-core tape optical fiber, comprising: an image pickup means arranged at an angular position where the image data can be taken in as an image. 19. A multi-core optical fiber image acquiring apparatus for arranging a plurality of coated optical fibers substantially in parallel and acquiring an image of a multi-core tape optical fiber having a common coating thereon. A slit light having a width larger than the width of the tape optical fiber and a thickness sufficiently smaller than the thickness of the multi-core tape optical fiber is incident on the surface of the multi-core tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the optical fiber. Optical means, a polarizing means having a plane of polarization set in a direction to reduce the amount of reflected light from the surface of the coating of the optical fiber, and reflection of the individual optical fibers from the surface of the coating via the polarizing means. A first imaging unit disposed at an angular position at which an image whose light amount is sufficiently large with respect to the amount of reflected light from the surface of the common coating can be obtained; An image acquisition apparatus for a multi-core tape optical fiber, comprising: a second imaging unit arranged at an angular position at which an image whose intensity is sufficiently large with respect to the amount of light reflected from the surface of the coating of the optical fiber can be acquired. 20. A multi-core tape optical fiber image acquiring apparatus for arranging a plurality of coated optical fibers substantially in parallel and acquiring an image of the multi-core tape optical fiber having a common coating thereon. The reflection angle of the reflected light from the surface of the common coating with respect to the longitudinal direction of the optical fiber becomes a Brewster angle with respect to the slit light having a thickness larger than the width of the tape optical fiber and sufficiently smaller than the thickness of the multi-core tape optical fiber. A light projecting means for entering the surface of the multi-core tape optical fiber at an incident angle, and the reflected light from the surface of the coating and the reflected light from the surface of the common coating of each of the optical fibers are the same image or two. An image acquisition apparatus for a multi-core tape optical fiber, comprising an image pickup means for taking in an image. 21. A light source-side polarizing means for polarizing the slit light in a direction in which the amount of reflected light from the surface of the common coating decreases, wherein the light projecting means has a light source side. An image acquisition device for a multi-core tape optical fiber according to any one of the preceding claims. 22. A multi-core tape optical fiber image acquisition device for arranging a plurality of coated optical fibers substantially in parallel and acquiring an image of a multi-core tape optical fiber having a common coating thereon. Projection means for causing slit light having a thickness larger than the width of the tape optical fiber and having a thickness sufficiently smaller than the thickness of the multi-core tape optical fiber to enter the surface of the multi-core tape optical fiber at a predetermined incident angle with respect to the longitudinal direction of the optical fiber. And projecting the numerical aperture of the reflected light from the surface of the common coating to the extent that the amount of reflected light from the surface of the coating and the amount of light reflected from the surface of the common coating of each of the optical fibers can be observed in the same image. Numerical aperture adjusting means for setting the numerical aperture of the incident light of the slit light to be larger than the numerical aperture of the slit light, and the coating of the individual optical fibers via the numerical aperture adjusting means. An image acquisition device for a multi-core tape optical fiber, comprising: imaging means arranged at an angular position for capturing an image of light reflected from the surface of the optical fiber and light reflected from the surface of the common coating as the same image. 23. The slit light which the light projecting means makes incident on the surface of the multi-core tape optical fiber has a spectrum in a wide wavelength range. Item 10. An image acquisition device for a multi-core tape optical fiber according to the above item. 24. A multi-core optical fiber for arranging a plurality of coated optical fibers substantially in parallel and detecting a relative position of each of said optical fibers from the surface of said common coating in a multi-core tape optical fiber having a common coating applied thereon. In the optical fiber relative position detection device of the tape optical fiber, a slit light having a width that is larger than the width of the multi-core tape optical fiber and a thickness that is sufficiently smaller than the thickness of the multi-core tape optical fiber is predetermined with respect to the longitudinal direction of the optical fiber. A light projecting means for entering the surface of the multi-core tape optical fiber at an angle of incidence, and an image of the light reflected from the surface of the coating and the light reflected from the surface of the common coating of each of the optical fibers being the same image or 2 Imaging means for capturing as one image, and calculating the relative positions of the individual optical fibers from the surface of the common coating from the images captured by the imaging means An optical fiber relative position detecting device for a multi-core tape optical fiber, comprising: