JP2000213912A - Core part eccentricity measuring device for optical fiber base material - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily and precisely measure a core part eccentricity in an optical fiber base material stage, to estimate a core eccentricity in an optical fiber stage based on a measured value, and to surely find out defectives in the optical fiber material stage. SOLUTION: Boundary lines between a core part and a clad part and between the clad part and an external space are clearly discriminated by directly observing an optical fiber base material 1 through an optical lens or by picking up an image on a monitor 6 using a CCD camera 3, via a polar screen 4. An upper panel 22 of a moving table 2 is moved in parallel to this direction with respect to a lower panel 21 of it to measure a moving amount of the upper panel 22 from the boundary line between the clad part and the external space to the boundary line between the clad part and the core part, a radial-directional dimension of the clad part is measured thereby, and a radial-directional dimension of the clad part in a contrary side sandwiching the core part is measured by the same manner. Then, the optical fiber base material 1 is rotated around a center axis by 90 degree to conduct measurement by the same manner. An eccentric amount of the core part is computed pursuant to plane geometry. A core eccentric amount in an optical fiber stage is estimated pursuant to a law of similarity.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of measuring the eccentricity of a core portion of an optical fiber preform (preform) to determine the eccentricity of the core of an optical fiber after drawing the optical fiber preform before drawing. The present invention relates to an optical fiber preform core eccentricity measuring device used for prediction.

[0002]

2. Description of the Related Art Conventionally, measurement of the amount of core eccentricity has been performed on an optical fiber after drawing from an optical fiber preform. The amount of core eccentricity of this optical fiber is determined by JIS (JIS
The amount of mode field eccentricity is determined by an optical fiber structure measuring instrument conforming to the NFP method (video analyzer method), image sharing method, or the like specified in C6825 “Single mode optical fiber structure parameter test method”. The measurement is performed by regarding the mode field eccentricity as the core eccentricity (core / cladding eccentricity). These include, for example, inputting a laser beam to one end in the axial direction of the optical fiber, measuring an electromagnetic field distribution of light transmitted through the optical fiber and output from the other end (NFP).
Method), display the intensity of the above output light level on a video camera and separate the image (image) into two (share)
Measurement.

[0003] Further, as an apparatus for measuring the eccentricity of a core portion at the stage of an optical fiber preform before drawing, instead of an optical fiber after drawing, a refractive index profile (refractive index distribution) of the optical fiber preform is measured. Preform analyzer (UK YORK TECHNOL, UK)
OGY LTD) is known. The measurement of the core eccentricity by this device is performed as follows. That is, first, as shown in FIG. 8, the optical fiber preform 1 contained in the cell 101 filled with the refractive index matching oil.
Then, a tungsten-halogen light (parallel beam) 102 is irradiated from the direction orthogonal to the longitudinal axis through the irradiation window of the cell 101, and the deflection angle of the light emitted from the optical fiber preform 1 is changed via a lens system 103. The optical fiber preform 1 is detected at each radial position. Next, the measured value of the declination is represented by a function of the declination with respect to the radial dimension of the optical fiber preform 1, and a calculation process is performed by a so-called personal computer using this function, whereby the refractive index profile with respect to the radial dimension is obtained. Get. Then, the position of the core in the optical fiber preform is estimated based on the refractive index profile, and the eccentricity of the core is obtained based on the relative positional relationship between the estimated position and the outer diameter of the optical fiber preform. That is.

[0004]

By the way, in the manufacturing process of manufacturing an optical fiber preform, manufacturing an optical fiber by drawing the optical fiber preform, and measuring the core eccentricity of the optical fiber, the manufacturing process of the optical fiber is as follows. If the measured value of the core eccentricity is equal to or greater than the specified value, the optical fiber is discarded, and not only the optical fiber itself is wasted, but also the work in the drawing step is wasted. On the other hand, since the cross-sectional structure of the optical fiber preform composed of the core and the clad, and the cross-sectional structure of the optical fiber composed of the core and the clad after drawing the optical fiber preform are generally similar, If the amount of eccentricity of the core portion is measured at the stage of the optical fiber preform before the drawing step and it is determined whether or not the eccentricity is within an allowable range, the occurrence of the waste can be prevented.

Therefore, it is conceivable to measure the eccentricity of the core portion at the stage of the optical fiber preform using the above-mentioned preform analyzer, and to predict the eccentricity of the core at the optical fiber stage based on the measured value.

However, in the measurement of the core eccentricity of the optical fiber preform by the above-described preform analyzer, although it can be measured from the principle, the periphery of the optical fiber preform is used to adjust the refractive index. Preparation work such as work for making the state filled with the matching oil is complicated and time-consuming, and the accuracy of the measurement of the deflection angle of the emitted light is low, and the process of obtaining the refractive index profile requires time. There is an inconvenience.

For this reason, the measurement of the core eccentricity at the stage of the optical fiber preform has been rarely performed, and the quality of the optical fiber is determined by measuring the core eccentricity at the stage of the optical fiber after drawing. In addition, with the recent increase in the diameter and length of the optical fiber preform, waste of materials and work tends to increase.

SUMMARY OF THE INVENTION The present invention has been made in view of such circumstances, and an object of the present invention is to make it possible to easily determine in advance an optical fiber preform at the optical fiber preform stage at the optical fiber preform stage. It is an object of the present invention to provide an optical fiber preform core eccentricity measuring device capable of preventing waste by early detection of defective products.

[0009]

Means for Solving the Problems To achieve the above object, the inventor of the present invention removes the reflected light component on the outer surface by looking at the optical fiber preform through a polarizing filter, and removes the optical fiber preform. Paying attention to the point that the boundary line resulting from the difference in the glass composition of the core part and the clad part that constitutes becomes visible,
The present invention has been conceived which makes it possible to easily measure the eccentricity of the core portion of the optical fiber preform by utilizing this.

More specifically, the present invention provides a support means for supporting an optical fiber preform so as to be rotatable about a central axis extending in a longitudinal direction thereof, and a reference to the optical fiber preform. An optical means having a point display and enlarging the optical fiber preform from a direction parallel to a viewing axis arranged in a direction orthogonal to the central axis, a polarizing filter attached to the optical means, and the support means Moving means for moving one of the optical means and the other in a fixed state, and moving the other in parallel along a moving axis arranged in a direction orthogonal to the central axis and the viewing axis, and movement of a specific section by the moving means It is a specific matter to provide a movement amount measuring means for measuring the amount.

Here, the above-mentioned "center axis", "visual axis" and "moving axis" constitute three axes orthogonal to each other.
The “viewing axis” and the “moving axis” form two orthogonal axes arranged on the cross section of the optical fiber preform.
In addition, "optical means" means, for example, in addition to a lens system configured by an eyepiece and an objective lens for magnifying,
What is necessary is just to comprise with a CCD camera etc., and "reference point display"
Is a display that defines a reference for a relative positional relationship between a visual field to be magnified by optical means and an optical fiber preform to be measured. For example, a mark of a “+” mark or a line segment parallel to the center axis is indicated by the above-mentioned eyepiece. Alternatively, it is displayed in advance on the lens system of the CCD camera.

In the case of the invention described above, the optical fiber preform is supported by the supporting means at an arbitrary rotational position about the center axis, and when the optical fiber preform in this state is magnified by the optical means, the light is transmitted through the polarizing lens. The boundary between the clad part and the core part becomes visible due to the difference in the glass composition inside the fiber preform. Then, by moving one of the support means or the optical means along the movement axis, first, a reference point in the visual field visible by the optical means is displayed with the outer surface of the optical fiber preform (the outer surface of the clad portion). The reference point is displayed between the clad portion and the core portion by further adjusting the boundary position between the clad portion and the core portion by adjusting the boundary position with the external space (the first boundary position), and then further moving along the movement axis. In accordance with the boundary position (second boundary position), the distance from the first boundary position to the second boundary position is set as a specific section, and the movement amount during that period is measured by the movement amount measurement means. From the measured value x ₁ (see FIG. 1), the radial dimension of the clad portion 12 on one side in the moving axis direction with the core portion 11 interposed therebetween can be obtained. Similarly, by further proceeding the movement along the movement axis, the reference point is displayed at the boundary position (third boundary) between the core portion 11 and the cladding portion 12 on the other side in the movement axis direction with the core portion 11 interposed therebetween. Position), and then further move along the movement axis to display the reference point at the boundary position between the cladding portion 12 on the other side in the movement axis direction and the external space (fourth boundary position). to the combined, when measured by the movement measuring means the amount of movement from the third boundary position to the fourth boundary position, the radial dimension of the moving shaft direction other side of the clad part 12 is obtained by the measured value x ₂ become.

Next, the optical fiber preform 1 is rotated around the central axis.
Supported by the support means at a rotation position rotated 90 degrees.
The optical fiber preform 1 after the rotation position conversion.
Repeat the same operation as. With this, the optical fiber preform
The above measured value x on the cross section of 1 ₁, X_TwoIs a 90-degree rotation
The radial dimension of the clad portion 12 on one side in the moving axis direction after the replacement
And the measured value y₁, The diameter of the cladding part 12 on the other side in the moving axis direction
Measured value y as dimension in direction_TwoWill be obtained respectively.
You.

When these measured values x ₁ , x ₂ , y ₁ and y ₂ are obtained, the distance δp between the center Cp of the optical fiber preform 1 and the center Cc of the core 11 (the amount of eccentricity of the core) ) Can be easily obtained by calculation by plane geometry using the above measured values.

That is, the diameter of the core portion 11 is d, the diameter of the optical fiber preform 1 is D, the movement axis when measuring x ₁ and x ₂ is the X axis, and the movement when measuring y ₁ and y _2. Axis is Y axis, δ above
The x-axis dimension of p is x, and the y-axis dimension of δp is y
Then, δp is expressed by the following equation (1).

Δp = (x ² + y ² ) ^1/2 (1) Further, the diameter D in the X-axis direction has the relationship of the formula (2).

D = x ₁ + d + x ₂ (2) Further, the range of a half of the diameter D in the X-axis direction has the relationship of the formula (3).

(1/2) D = x + (1/2) d + x ₂ Therefore, D = 2x + d + 2x ₂ (3) d is eliminated by making each right side of the above equations (2) and (3) equal. When x is arranged, x = (x ₁ −x ₂ ) / 2 (4) is obtained. The same applies to the Y-axis direction.
Leads to Equation (5).

Y = (y ₁ −y ₂ ) / 2 (5) Then, by substituting the above equations (4) and (5) into the above equation (1) and rearranging, the following equation (6) is obtained. .

Δp = ｛(x ₁ −x ₂ ) ² + (y ₁ −y ₂ ) ² ｝ ^1/2 (6) Therefore, the above measured values x ₁ , x ₂ , y ₁ , y ₂ are calculated as follows. Above (6)
By substituting into the equation, the core eccentricity δp can be easily and accurately obtained.

Based on this δp, the core eccentricity δf at the optical fiber stage after drawing may be estimated as follows. That is, assuming that the cross-sectional structure of the optical fiber preform and the cross-sectional structure of the optical fiber are similar to each other, the following expression (7) is established based on the similarity rule.

Δp / D = δf / Df (7) Here, when the optical fiber outer diameter Df is changed to 125 μm, δf = δp × (125 / D) (8) The above four measured values x _1, the operation of the core unit core eccentricity δp of the optical fiber preform by the above equation (6) based on the x _2, y _1, y _2, after drawing by the above (8) based on this δp It is possible to estimate the core eccentricity δf of the optical fiber.

The base material diameter D can be determined by the present measuring device or other measuring means such as a caliper and a laser external measuring device.

When positioning the reference point display with respect to each of the first to fourth boundary positions, the optical fiber preform is illuminated from a direction opposed to the optical means with the optical fiber preform interposed therebetween. By providing the light source that gives light, it becomes possible to more clearly recognize the boundary positions through the polarizing filter. Further, in addition to the operator directly viewing the image through the eyepiece, by displaying the image of the optical fiber preform magnified by the optical means on the monitor together with the reference point display, the above-described positioning can be performed more easily and reliably. . At this time, the display on the monitor is specifically realized by using a CCD camera as an optical unit and connecting the monitor and the CCD camera so that the output signal from the CCD camera is received and displayed on the monitor. It becomes possible to do.

[0025]

As described above, according to the position of measuring the eccentricity of the core of the optical fiber preform of the present invention, the boundary between the core and the cladding can be visually recognized through the polarizing filter. Can be clearly identified, and the amount of eccentricity of the core can be easily and accurately measured by a simple operation of merely measuring the movement amount while visually recognizing the boundary line. For this reason, it is possible to determine in advance whether or not the core eccentricity is possible in the optical fiber stage based on the measured value of the core eccentricity in the optical fiber preform stage, and it is possible to prevent waste by early detection of defective products. .

[0026]

Embodiments of the present invention will be described below in detail with reference to the drawings. <First Embodiment> FIG. 2 shows an optical fiber preform core eccentricity measuring apparatus according to a first embodiment of the present invention, wherein 1 is an optical fiber preform to be measured and 2 is a movement as a support means. The table 3, 3 is a CCD camera as an optical means, 4 is a polarizing filter, 31 is an objective lens, 5 is on the opposite side to the CCD camera 3 across the optical fiber preform 1 along the visual axis S of the CCD camera 3. A lamp as a light source arranged, 6 is a monitor connected to the CCD camera 3 and 7 is an arithmetic unit which is connected to the moving table 2 and serves as moving amount measuring means for measuring the moving amount of the moving table. is there.

The optical fiber preform 1 is arranged so that the central axis P is directed, for example, in the horizontal direction, and has a core section 11 (see FIG. 1) having a circular cross-section formed at a substantially central position, and is formed therearound. The cladding 12 has a circular cross section.

As shown in FIG. 3, the movable table 2 is mounted on a base plate (not shown) and fixed in position.
The lower plate 21 is provided with an upper plate 22 which is slidably guided on a horizontal plane in parallel along a movement axis M orthogonal to the center axis P. The optical fiber preform 1 is held on the upper platen 22 at a predetermined rotational position about the central axis P. In addition, the lower plate 21 and the upper plate 22 are each provided with an opening at the center position,
A transparent glass plate 221 is fitted in at least one opening. The illumination light of the lamp 5 is applied to the optical fiber preform 1 through the opening. Further, the moving table 2 is an amount of parallel movement of the upper plate 22 along the moving axis M with respect to the lower plate 21, that is,
A means (for example, a rotary encoder) for electrically detecting the parallel movement amount of the optical fiber preform 1 along the movement axis M is provided, and the movement of a specific section is performed based on a switch signal from the arithmetic unit 7 described later. The amount is to be measured.

The CCD camera 3 is disposed so that its visual axis S passes through the intersection of the central axis P and the moving axis M and is orthogonal to both axes P and M. 1 can be magnified when the focus is adjusted via the polarizing filter 4. Then, the CCD camera 3 is marked with a crosshair as a reference point display in the field of view, and an image of the optical fiber preform 1 which is magnified together with the crosshairs 32 and 33 is displayed on the monitor 6 as shown in FIG. It is displayed. The monitor 6 shows a state in which the optical fiber preform 1 is viewed through the polarizing filter 4, that is, each boundary between the core 11 extending substantially along the central axis P and the claddings 12 on both sides thereof. The position is displayed in a state where it can be clearly identified. In addition, the central axis P is displayed in parallel with the horizontal cross line 33, and the movement axis M is displayed in a state in which the vertical axis 32 matches.
Then, by moving the upper plate 22 of the movable table 2 along the movement axis M, the optical fiber preform 1 moves downward in FIG.

The arithmetic unit 7 includes a measurement switch 71 operated by an operator, an input / output interface, a CPU for performing arithmetic processing, and a printer 72 for outputting the calculation result. By operating the switch 71, the optical fiber preform 1
The parallel movement amount of a specific section along the movement axis M is measured and stored. Then, based on the stored measurement value, the core eccentricity δp of the optical fiber preform 1 and the estimated value of the core eccentricity δf of the optical fiber based on the calculated eccentricity δp by the above-described equation (6), The calculation result is output by the printer 72.

Next, the procedure for measuring the core eccentricity δp of the optical fiber preform 1 by the above-described core eccentricity measuring apparatus will be described. (The first rotation position), and is fixed on the upper plate 22 of the movable base 2, and the upper plate 22 is positioned behind the visual axis S. Then, while watching the monitor 6, the upper plate 22 is moved in parallel with the optical fiber preform 1 little by little toward the front along the movement axis M. When the horizontal cross line 33 on the image on the monitor 6 matches the boundary line b ₁ (first boundary position; see FIG. 4) between the clad portion 12 in front of the optical fiber preform 1 and the external space, the parallel movement is stopped. Then, the switch 71 is pressed to perform an input operation. Thereby, a zero value is initially set as an initial value of the movement amount measurement. Next, when the upper plate 22 is translated again, the optical fiber preform 1 on the monitor 6 is further moved in the direction of the arrow in FIG. The movement of the upper platen 22 is stopped again when the boundary line b ₂ (the second boundary position) is reached. Then, the switch 71 is pressed again to perform an input operation. Thus, the arithmetic unit 7, the moving amount x ₁ along the movement axis M of the optical fiber preform 1 of the specific section from the border b ₁ to the border line b ₂
(See FIG. 1) is measured and stored.

Further, the upper platen 22 is moved, and when the cross horizontal line 33 coincides with the boundary line b ₃ (third boundary position) between the core portion 11 and the rear clad portion 12, the upper platen 2 is moved.
The movement of No. 2 is stopped, and a zero value is reset as an initial value of the movement amount measurement by an input operation using the operation switch 71. And, as in the previous operation,
Is moved again, and when the horizontal cross line 33 coincides with the boundary line b ₄ (fourth boundary position) between the rear clad portion 12 and the external space, the input operation is performed by the operation switch 71, whereby the arithmetic unit 7 is operated. Then, from the boundary line b ₃ to the boundary line b ₄
Until the movement amount x ₂ optical fiber preform 1 in this specific section will be stored is measured as the specific interval.

As described above, a pair of movement amounts (measured values) x ₁ and x ₂ are obtained. That is, the X-axis shown in FIG. 1 is matched with the moving axis M, and x ₁ and x ₂ , which are dimensions in the X-axis direction, are obtained as measured values.

Next, from the first rotation position, the center axis P
The optical fiber preform 1 is fixed at a second rotation position rotated around 90 degrees. As a result, the Y axis shown in FIG. Then, the same operation as the measurement at the first rotation position is repeated again, and Y
The axial dimensions y ₁ and y ₂ are obtained as measured values.

Then, these two pairs of measured values x ₁ , x ₂ , y
₁ and y ₂ are substituted into the equation (6) to calculate the core eccentricity δp. Subsequently, the core eccentricity is substituted into the δp (8) equation to estimate the core eccentricity at the optical fiber stage. δf is calculated, and both values δp and δf are output by the printer 72. <Second Embodiment> FIG. 5 shows an optical fiber preform core eccentricity measuring apparatus according to a second embodiment.
1 and an eyepiece 82, a magnifying glass as optical means arranged along the visual axis P, and the objective lens 81
The polarizing filter 4 is attached to the tip of the.

Since the other components are the same as those of the first embodiment, the same components are denoted by the same reference numerals and detailed description thereof will be omitted.

In the second embodiment, the core eccentricity δp and the predicted value δf of the core eccentricity at the optical fiber stage can be easily obtained by the same measurement operation as in the first embodiment.

That is, as shown in FIG. 6, a cross line 83 as a reference point display
When the operator looks directly into the eyepiece lens 82, the horizontal cross line 84 and the boundary lines b1 to b4 similar to those of the first embodiment are matched with each other. If operated, the movement amount from the boundary line b1 to b2 and the movement amount from the boundary line b3 to b4
And the amount of movement up to. <Other Embodiments> The present invention is not limited to the first and second embodiments, but includes various other embodiments. That is, in the first and second embodiments, the lamp 5 is provided, but the invention is not limited to this.
It may be omitted. Even in this case, each boundary line between the clad portion 12 and the core portion 11 in the optical fiber preform 1 and each boundary line between the clad portion and the external space in the optical fiber preform 1 are clearly identified through the polarizing filter by receiving the light of the room illumination. I can do it.

[0039]

EXAMPLE The core eccentricity of an optical fiber preform actually manufactured using the measuring apparatus of the second embodiment was measured,
Based on the measured values, a predicted value of the core eccentricity at the optical fiber stage was calculated. Then, the core eccentricity of the optical fiber actually drawn using the optical fiber preform was measured, and the correlation between the predicted value and the actual core eccentricity was examined.

At the time of measurement, first, the necessary resolution for the measurement was examined. Since the resolution (accuracy) of the core eccentricity at the optical fiber stage is 0.01 μm, setting the resolution at the optical fiber preform stage at which the above-described predicted value will be substantially the same as this resolution is performed. I do. Assuming that the ratio of the resolution to the outer diameter is the same in the optical fiber stage and the optical fiber preform stage, the following relationship is established. Here, the resolution (accuracy) of the optical fiber preform is Δδp, and the outer diameter of the optical fiber after drawing is 125 μm.

0.01 / 125 = Δδp / D Therefore, Δδp = (0.01 / 125) × D This relationship is obtained for the optical fiber preform having an outer diameter D of 45, 60, and 80 mm. Table 1 shows the results.

[0042]

[Table 1] In this embodiment, the resolution Δδp is set to 0.004 mm in relation to the minimum value of Δδp in Table 1. This Δδ
p is a value sufficiently possible with a commercially available rotary encoder.

Further, as a result of trial and error with respect to the magnification of the objective lens 81, the resolution is poor at 1 × and the boundary line b1 and the like are too large at 5 ×, so that the magnification of the objective lens 81 is 3 in this embodiment. Set the times.

Then, fifteen base materials (the number of measurements: n = 2)
The core eccentricity was measured for 2), and the measured values x ₁ ,
x ₂ , y ₁ , y ₂ , the core eccentricity δp of the optical fiber preform based thereon, the predicted value δf of the core eccentricity of the optical fiber stage based on this, and the actual core eccentricity of the optical fiber are obtained. Was done.

FIG. 7 shows the relationship between the obtained predicted value δf of the core eccentricity at the optical fiber stage and the actual core eccentricity of the optical fiber. According to this, a substantially linear relationship is observed between the predicted value δf and the actual core eccentricity of the optical fiber, and based on the measured value of the core eccentricity at the optical fiber preform stage according to the present embodiment. It can be seen that the core eccentricity at the optical fiber stage can be accurately predicted.

[Brief description of the drawings]

FIG. 1 is an explanatory cross-sectional view of an optical fiber preform in which a state in which a core portion is eccentric is exaggerated in order to explain a principle of obtaining an eccentricity amount of a core portion of the present invention.

FIG. 2 is a schematic view of a core measuring device according to the first embodiment.

FIG. 3 is an explanatory sectional view taken along line AA of FIG. 2;

FIG. 4 is an enlarged front view of the monitor.

FIG. 5 is a schematic view of a core measuring device according to a second embodiment.

FIG. 6 is an explanatory diagram showing a state in a field of view of the eyepiece of FIG. 5;

FIG. 7 is a diagram illustrating a relationship between a predicted value of core eccentricity at the optical fiber stage and an actual core eccentricity of an optical fiber.

FIG. 8 is a principle diagram showing a conventional preform analyzer for estimating a core eccentricity of an optical fiber preform.

[Explanation of symbols]

 Reference Signs List 1 optical fiber preform 2 moving table (supporting means, moving means) 3 CCD camera (optical means) 4 polarizing filter 5 lamp (light source) 6 monitor 8 magnifying mirror (optical means) 11 core part 12 clad part M moving axis P center Axis S Visual axis

Claims (5)

[Claims] A support means for supporting the optical fiber preform so as to be rotatable about a central axis extending in a longitudinal direction thereof; and a reference point indicating the optical fiber preform and having the optical fiber preform centered on the optical fiber preform. An optical unit disposed in a direction perpendicular to the axis and enlarging from a direction parallel to the visual axis; a polarizing filter attached to the optical unit; and the other in a state where one of the support unit and the optical unit is fixed. Moving means for parallel moving along a moving axis arranged in a direction orthogonal to both the central axis and the visual axis, and a moving amount measuring means for measuring a moving amount of a specific section by the moving means. An optical fiber preform core eccentricity measuring device, characterized in that: 2. An optical fiber preform according to claim 1, further comprising a light source for applying illumination light to the optical fiber preform from a direction opposite to the optical means with the optical fiber preform interposed therebetween. Core eccentricity measuring device for material. 3. An optical fiber preform core eccentricity measuring apparatus according to claim 1, further comprising a monitor for displaying an image of the optical fiber preform magnified by the optical means together with a reference point display. . 4. The apparatus according to claim 3, wherein the optical means is a CCD camera, and the monitor is configured to receive and output the output signal from the CCD camera.
An optical fiber preform core eccentricity measuring device, which is connected to a camera. 5. The eccentricity of a core portion of an optical fiber preform according to claim 1, wherein the supporting means and the moving means are constituted by a moving table for moving the optical fiber preform while being placed thereon. Quantity measuring device.