JP2003222740A - Polarization retention photonic crystal fiber - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a polarization retention photonic crystal fiber that can easily discriminate a polarization surface by observation using a microscope. <P>SOLUTION: Since a pair of pores 4b that oppose each other by sandwiching a core 1 in six pores 4a and 4b adjacent to the core 1 has a diameter larger than the other four pores 4a, a polarization retention photonic crystal fiber 10 has a polarization-retaining function. The section of a cladding section 2 comprising a number of pores 4a and 4b at the periphery of the core 1 is in a diamond shape. Therefore, the maximum width of the cladding section 2 observed from the side of the fiber 10 appears each time when the fiber 10 is rotated by 180°, and the minimum width also appears in the similar manner. Since the width directions of the maximum and minimum widths coincide with the polarization direction of the polarization surface, the direction of the polarization surface of the polarization retention photonic crystal fiber 10 can be discriminated by microscope observation from the side of the fiber 10. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a clad portion in which a large number of pores extending in the optical fiber axial direction are arranged in a crystalline form around a core, and an over clad portion provided around the clad portion. A polarization-maintaining photonic crystal fiber provided with.

[0002]

2. Description of the Related Art In recent years, a photonic crystal fiber has attracted attention as a material exhibiting a large chromatic dispersion that cannot be obtained by an ordinary optical fiber composed of a core and a clad. This photonic crystal fiber has a clad part in which a large number of pores extending in the optical fiber axial direction are arranged in a crystal shape around the core, and an overcoat provided around the clad part to further support the clad part. And a clad portion.

On the other hand, a polarization maintaining fiber having high polarization stability is used for an optical fiber sensor utilizing polarization and interference, coherent optical fiber communication and the like. The use of the photonic crystal fiber as a polarization-maintaining photonic crystal fiber is also being considered by taking advantage of its wavelength dispersion characteristics. As described above, in order to make the photonic crystal fiber into a polarization-maintaining fiber, the cores or pores in the vicinity of the cores should be carefully arranged, for example, the cross-sectional shape of the core should be elliptical or rectangular, or the fine particles adjacent to the core should be made. A part of the pores may have a diameter different from that of the other pores.

By the way, when the ends of two optical fibers are fused and joined together, the side faces of the optical fibers are enlarged and observed, the ends of the optical fibers are aligned with each other, and the end faces are abutted with each other. There is. A microscope or the like is used for such magnified observation. In splicing polarization-maintaining fibers,
Furthermore, it is necessary to match the polarization planes of the two fibers. PAN used as a conventional polarization-maintaining fiber
In the DA fiber, since the stress-applying portions arranged on both sides of the core have different refractive indexes from other portions, the polarization planes can be distinguished by observing with a microscope. Therefore, it is relatively easy to match the polarization planes of the two fibers. You can

[0005]

However, when the polarization-maintaining photonic crystal fiber is observed from the side with a microscope, the cladding portion looks black because the refractive index of the pores is lower than that of silica glass, but the polarization plane is discriminated. The part around the core that can be formed is hidden by many pores around it, and the polarization plane cannot be discriminated. Therefore, the polarization planes of the two polarization-maintaining photonic crystal fibers should be aligned and joined together. It was very difficult.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a polarization-maintaining photonic crystal fiber whose polarization plane can be easily discriminated by observation with a microscope.

[0007]

To achieve the above object, either the maximum width or the minimum width of the cladding observed from the side of the fiber is 90% when the fiber is rotated around the central axis. A polarization-maintaining photonic crystal fiber having a clad formed so that it appears every 180 degrees or 180 degrees.

[0008] Specifically, in the invention of claim 1, a clad portion in which a large number of pores extending in the axial direction of the optical fiber are arranged in a crystal form around the core, and the clad portion is provided around the clad portion. A polarization-maintaining photonic crystal fiber having an overclad portion is assumed.

Then, the width of the cladding portion observed from the side of the fiber is changed by the rotation around the central axis of the fiber, and the fiber is moved from the position where either the maximum width or the minimum width of the cladding portion is observed. When the rotation angle is about the central axis, the width of the clad portion is smaller than the maximum width or larger than the minimum width when the rotation angle is 0 degree and smaller than 180 degrees, and
By arranging the pores so that when the rotation angle becomes 180 degrees, the width becomes substantially the same as either the maximum width or the minimum width at the rotation angle of 0 degrees, the polarization plane to be held can be displayed. It is assumed to be configured in.

Here, the fact that a large number of pores are arranged in a crystalline form means that a large number of pores are regularly arranged in the cross section of the fiber. For example, the minimum unit is an equilateral triangle, Examples include a square or rectangular lattice array. The pores preferably have a diameter of 0.1 to 10 μm in terms of fiber characteristics. In addition, the fact that the width of the clad part observed from the side of the fiber changes due to rotation around the central axis of the fiber is because the clad part in the cross section of the fiber has a different shape from the circular shape. During rotation of 360 degrees, at least one maximum diameter and at least one minimum diameter appear.

According to the first aspect of the invention, the specific radial direction of the cross section of the fiber can be determined by observing the fiber from the side of the microscope. Therefore, two polarization planes orthogonal to each other can be distinguished from each other, which is easy. In addition, the polarization maintaining photonic crystal fiber and another optical fiber can be joined with their polarization planes aligned. That is, the width direction of the maximum width or the minimum width of the clad viewed from the fiber side is
In the fiber cross section, since there is one specific radial direction, the maximum width or the minimum width appears again when the fiber is rotated about the central axis by 180 degrees, and therefore,
If the specific radial direction and the respective polarization directions of the two polarization planes orthogonal to each other are associated in advance, the two polarization planes can be distinguished and distinguished from each other. In other words, when the optical fiber of the invention of claim 1 is rotated around the central axis from the position where either the maximum width or the minimum width of the clad portion is observed, the rotation angle is 0 degree again. Is a polarization-maintaining photonic crystal fiber in which the minimum value of the rotation angle at which the maximum width or the minimum width is observed is 180 degrees.

The optical fiber according to the invention of claim 1 may be a polarization-maintaining photonic crystal fiber which is a birefringent optical fiber in which light propagates in both of two polarization planes orthogonal to each other, but two polarizations orthogonal to each other may be used. It is preferable that the polarization maintaining photonic crystal fiber is a single polarization optical fiber in which only one of the wavefronts propagates light. Other optical fibers that are fiber spliced include polarization maintaining photonic crystal fibers or other types of polarization maintaining fibers.

If the ratio of the maximum width to the minimum width of the clad portion observed from the side of the fiber is 1.2 to 5, then either the maximum width or the minimum width and the other width can be distinguished by microscopic observation. It is preferable because it is easy to attach and is easy to manufacture as a photonic crystal fiber.

Next, the invention of claim 2 is such that
It is assumed that a polarization maintaining photonic crystal fiber is provided with a clad part in which a large number of pores extending in the axial direction of the optical fiber are arranged in a crystal form, and an over clad part provided around the clad part.

The width of the clad portion observed from the side of the fiber is changed by the rotation around the central axis of the fiber, and the fiber is detected from the position where either the maximum width or the minimum width of the clad portion is observed. When the clad is rotated about the central axis, the width of the clad portion is smaller than the maximum width or larger than the minimum width when the rotation angle is 0 degree and smaller than 90 degrees, and the rotation angle is When the angle becomes 90 degrees, the pores are arranged so that the width becomes substantially the same as either the maximum width or the minimum width at the rotation angle of 0 degree, so that the polarization plane to be held is displayed. It has been done.

According to the second aspect of the present invention, the polarization plane can be identified by observing with a microscope from the side of the fiber. Therefore, the polarization-maintaining photonic crystal fiber and another optical fiber can be easily made to have the same polarization plane. Can be joined together. That is, since the width direction of either the maximum width or the minimum width of the clad portion viewed from the side of the fiber is two specific orthogonal radial directions in the cross section of the fiber, the fiber is rotated by 90 degrees about the central axis. The maximum width or the minimum width appears again when rotated, and therefore if the specific radial direction and the polarization direction of the polarization plane are associated in advance,
The two planes of polarization orthogonal to each other can be discriminated without distinction. In other words, when the optical fiber of the invention of claim 2 is rotated around the central axis from the position where either the maximum width or the minimum width of the clad portion is observed, the rotation angle is 0 degree again. Is a polarization-maintaining photonic crystal fiber in which the minimum value of the rotation angle at which the maximum width or the minimum width is observed is 90 degrees.

Since the optical fiber according to the second aspect of the present invention does not distinguish two polarization planes orthogonal to each other, it is a polarization-maintaining photonic crystal fiber which is a birefringent optical fiber in which light propagates in both polarization planes. Is preferred.
Other optical fibers to be spliced may be polarization maintaining photonic crystal fibers or other types of polarization maintaining fibers.

If the ratio of the maximum width and the minimum width of the clad portion observed from the side of the fiber is 1.2 to 5, it is possible to distinguish between the maximum width or the minimum width and other widths by microscopic observation. It is preferable because it is easy to attach and is easy to manufacture as a photonic crystal fiber.

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

First Embodiment FIG. 1A shows an end face of the polarization maintaining photonic crystal fiber 10 according to the first embodiment. In this polarization-maintaining photonic crystal fiber 10, a large number of pores 4a and 4b extending in the optical fiber axial direction are arranged around a core 1 made of quartz glass in a clad in which the minimum unit is arranged in a crystal shape of an equilateral triangle lattice. A portion 2 and an over cladding portion 3 made of quartz glass are provided around the cladding portion 2. The clad portion 2 is formed by arranging the pores 4a and 4b so that the outer shape of the clad portion is rhombic.

In this polarization maintaining photonic crystal fiber 10, the six pores 4a and 4b adjacent to the core 1 are provided.
Among them, a pair of pores 4b facing each other with the core 1 interposed therebetween are
The diameter is larger than the other four pores 4a. By arranging the pores 4a and 4b in this manner, the polarization maintaining function is provided in the optical fiber 10. That is, a pair of large-diameter pores 4b
A polarization plane that includes a straight line connecting the centers of the two and is perpendicular to the fiber cross section (hereinafter referred to as the first polarization plane) and a polarization plane that is orthogonal to the cross section (hereinafter referred to as the second polarization plane) Due to the arrangement of the holes 4a and 4b, there is a difference in the propagation constant between the two propagating polarization modes, so that the polarization is retained in the optical fiber 10.

Of the two diamond-shaped diagonal lines of the clad portion 2, the shorter diagonal line extends in the polarization direction of the first polarization plane, and the longer diagonal line of the second polarization plane. It extends in the polarization direction.

Next, it will be described that the direction of the plane of polarization can be determined when the polarization-maintaining photonic crystal fiber 10 is observed with a microscope.

FIG. 1B is a schematic view of an end face of the polarization maintaining photonic crystal fiber 10. When the polarization-maintaining photonic crystal fiber 10 is observed from the side with a microscope, the portion of the clad portion 2 formed of the pores 4a and 4b is the overclad portion 3 that is a portion only made of silica glass.
Since it has a lower refractive index than that, it looks black. As shown in FIG. 1C, when the fiber 10 is rotated around the central axis,
The width of the clad portion 2 observed from the side of the fiber 10 is
It changes like a sine curve. When viewed from the X direction in FIG. 1 (B), the maximum width of the clad portion 2 is observed, and when the fiber 10 is rotated clockwise from that, the width of the clad portion 2 gradually decreases to 90 degrees. When rotated, the minimum width (as viewed from the Y direction) is observed. When further rotated, the width of the clad portion 2 gradually increases, and when rotated 180 degrees from X (as viewed from the Z direction), the maximum width is observed again. Therefore,
The plane orthogonal to the X or Z direction can be determined to be the second polarization plane, and the plane orthogonal to the Y direction can be determined to be the first polarization plane. By observing with a microscope when the crystal fiber 10 is bonded, two orthogonal polarization planes can be distinguished and easily matched.

That is, the width of the cladding portion 2 observed from the side of the fiber 10 was changed by the rotation of the fiber 10 around the central axis, and either the maximum width or the minimum width of the cladding portion 2 was observed. Fiber from position 1
When 0 is rotated around the central axis, the width of the clad portion 2 becomes smaller than the maximum width or larger than the minimum width at a rotation angle of 0 degree when the rotation angle is larger than 0 degree and smaller than 180 degrees. Thus, when the rotation angle becomes 180 degrees, the pores 4a and 4b are arranged so that the clad portion 2 is formed to have substantially the same width as the maximum width or the minimum width at the rotation angle of 0 degree. This means that the cladding 2
That is, by arranging the pores 4a and 4b so as to have a rhombic cross section, the polarization plane to be held is displayed. Moreover, in the present embodiment, the ratio of the maximum width to the minimum width of the clad portion 2 is about 1.7, so when the fiber 10 is rotated, X, Y, Z
It is easy to identify the direction.

Compared with the polarization-maintaining photonic crystal fiber 10 according to this embodiment, the conventional polarization-maintaining photonic crystal fiber 20 shown in FIG. Observing from above, since either the maximum width or the minimum width of the cladding portion 2 appears every time the fiber 20 is rotated by 60 degrees, the polarization plane cannot be discriminated. Further, since the ratio of the maximum width to the minimum width of the clad portion 2 is about 1.16, it is difficult to distinguish the maximum width and the minimum width. Therefore, in the conventional polarization maintaining photonic crystal fiber 20, the fiber 20
Depending on the microscopic observation from the side, two fibers 20
It is not possible to join them by matching the polarization directions of.

Next, a method of manufacturing the polarization maintaining photonic crystal fiber 10 according to this embodiment will be described.

First, a SiO ₂ cylindrical support tube is prepared. This support pipe is a portion that becomes the overclad portion 3, has a large thickness as a pipe, and has an outer diameter of about 2 to 5 times the inner diameter. Then, the inner wall of the support tube is ground to have a rhombic cross section.

Next, one SiO ₂ cylinder (rod) having the same outer diameter, two SiO ₂ large inner diameter thin tubes (capillaries), and a large number of SiO ₂ small inner diameters. Prepare a thin tube (capillary). The rod is arranged in the center of the support tube as a core, and the large inner diameter capillaries are arranged on both sides of the rod on the diagonal of the shorter side of the rhombus, and The remaining portion is filled with the small-inner-diameter capillary to produce a preform which is a fiber preform.
The arrangement of rods and capillaries in the preform is the same as that shown in FIG. 1 (A).

The support tube and rod are the VAD method,
It may be manufactured by a known method such as the OVD method or the MCVD method. The capillaries may be formed by a wire drawing process in which a capillary base material, which is a cylindrical member having a relatively large diameter, is heated and drawn to reduce its diameter.

The preform thus produced is dehydrated with chlorine gas or the like, heated in a drawing furnace, and then subjected to a drawing process in which it is drawn to be thinned (fiberized) into an optical fiber. . It is preferable to seal the end portion of the preform before the drawing step because it prevents the pores from being crushed during the drawing step.

When drawn into an optical fiber, since the support tube and the capillary, the capillary and the rod, and the capillaries are made of the same material, they are fused and integrated so that there is no boundary, and the polarization maintaining photonic shown in FIG. It becomes a crystal fiber 10.

As described above, in the polarization-maintaining photonic crystal fiber 10 according to this embodiment, the cladding portion 2 is formed by arranging the pores 4a and 4b in a diamond shape, and is observed from the side of the fiber 10. At fiber 1
Every time 0 is rotated about the central axis by 180 degrees, the maximum width and the minimum width of the clad portion 2 appear, and the directions in which the maximum width and the minimum width are observed are two orthogonal polarization planes. Since they coincide with the polarization directions, by observing the side surface of the fiber 10 by enlarging it with a microscope, the directions of the two polarization planes orthogonal to each other can be distinguished and easily discriminated. Therefore, the polarization maintaining photonic crystal fibers 10 or the polarization maintaining photonic crystal fiber 10 and another polarization maintaining fiber or the like can be easily joined in a short period of time in a splicing operation. Even if the skill level of the operator is low, accurate joining can be performed. Therefore, the cost of joining work can be reduced. Further, the manufacture of the polarization maintaining photonic crystal fiber 10 according to the present embodiment is
Since the inside of the support tube to be the over-clad portion 3 is ground so as to have a rhombic cross section and the capillaries and rods are packed therein, manufacturing can be performed easily in a short time and manufacturing cost can be reduced.

-Second Embodiment- FIG. 2A is a schematic view of an end face of a polarization maintaining photonic crystal fiber 10 according to a second embodiment.
In the present embodiment, the pores 4a and 4b are arranged so that the cladding 2 has an elliptical cross-sectional outer shape. The major axis direction of the ellipse substantially coincides with the polarization direction of the first polarization plane.
When the fiber 10 is observed from the side of the fiber 10 while rotating the fiber 10 around the central axis also in this embodiment, the maximum width of the cladding portion 2 appears every time the fiber 10 is rotated by 180 degrees, as shown in FIG. Since the narrow width also appears, the function and effect are similar to those of the first embodiment. In addition, the polarization maintaining photonic crystal fiber 10 of the present embodiment is
Since the ratio between the maximum width and the minimum width of the clad portion 2 can be easily increased while maintaining the function as the photonic crystal, it is easy to determine the maximum diameter and the minimum diameter. The manufacturing method is also the same as in the first embodiment.

-Third Embodiment- FIG. 3A is a schematic view of an end face of a polarization maintaining photonic crystal fiber 10 according to a third embodiment.
In the present embodiment, the pores 4a and 4b are arranged such that the cross-sectional outer shape of the clad portion 2 has a keyhole shape in which the outer circumference of a circle partially projects outward in a rectangular shape. According to the present embodiment, when the fiber 10 is observed from the side of the fiber 10 while rotating the fiber about the central axis, the maximum width of the cladding portion 2 appears every 180 degrees as shown in FIG. 3B. Since the large width direction substantially coincides with the polarization direction of the first polarization plane, the operation effect is the same as that of the first embodiment. The manufacturing method is also the same as in the first embodiment.

-Fourth Embodiment- FIG. 4A is a schematic view of an end face of a polarization-maintaining photonic crystal fiber 10 according to a fourth embodiment.
In this embodiment, the pores 4a and 4b are arranged so that the clad 2 has a right-angled triangular cross-section. In the present embodiment, when the fiber 10 is rotated around the central axis and observed from the side of the fiber 10, the maximum width of the clad portion 2 appears every 180 ° rotation as shown in FIG. Appears similarly, and the width direction of this maximum width substantially coincides with the polarization direction of the first polarization plane, so that the operation effect is the same as that of the first embodiment. Furthermore, when the fiber 10 is rotated clockwise in the figure, the minimum width becomes the maximum width at a rotation angle of less than 90 degrees, which makes it easy to determine.
The manufacturing method is also the same as in the first embodiment.

-Fifth Embodiment- FIG. 5A is a schematic view of an end face of a polarization-maintaining photonic crystal fiber 10 according to a fifth embodiment.
In this embodiment, the pores 4a and 4b are arranged so that the cross-sectional outer shape of the clad portion 2 is an isosceles triangle.
In this embodiment, when the fiber 10 is observed from the side of the fiber 10 while rotating it about the central axis, the minimum width of the cladding portion 2 appears every 180 degrees as shown in FIG. Since the width direction of the narrow width substantially coincides with the polarization direction of the first polarization plane, the function and effect are similar to those of the first embodiment. The manufacturing method is also the same as in the first embodiment.

-Sixth Embodiment- FIG. 6A is a schematic view of an end face of a polarization maintaining photonic crystal fiber 10 according to a sixth embodiment.
In this embodiment, the pores 4a and 4b are arranged so that the clad 2 has a rectangular cross-section. In the present embodiment, when the fiber 10 is observed from the side of the fiber 10 while rotating it about the central axis, the minimum width of the cladding portion 2 appears every 180 ° rotation as shown in FIG. 6B. Since the width direction of the narrow width substantially coincides with the polarization direction of the first polarization plane, the function and effect are similar to those of the first embodiment. Furthermore, since the maximum width becomes the minimum width at a rotation angle smaller than 90 degrees and the ratio of the maximum width to the minimum width can be easily increased while maintaining the function as the photonic crystal, it is easy to determine the maximum diameter and the minimum diameter. . The manufacturing method is also the same as in the first embodiment.

-Seventh Embodiment- FIG. 7A is a schematic view of an end surface of a polarization maintaining photonic crystal fiber 10 according to a seventh embodiment.
In the present embodiment, the pores 4a and 4b are arranged so that the clad 2 has a square cross section. In this embodiment, when the fiber 10 is rotated around the central axis and observed from the side of the fiber 10, the maximum width and the minimum width of the cladding portion 2 appear every 90 ° rotation, as shown in FIG. 7B. , Since the width direction of this maximum width is substantially coincident with the polarization direction of the first or second polarization plane, two orthogonal polarization planes cannot be distinguished from each other, but the other action and effect are: This is similar to the first embodiment. That is,
The width of the clad portion 2 observed from the side of the fiber 10 is
When the fiber 10 is rotated around the central axis from the position where either the maximum width or the minimum width of the clad 2 is observed, the width of the clad 2 changes depending on the rotation of the fiber 10 around the central axis. , When the rotation angle is larger than 0 degree and smaller than 90 degrees, it becomes smaller than the maximum width or larger than the minimum width, and when the rotation angle becomes 90 degrees, the maximum width or the minimum width at the rotation angle of 0 degree. The pores 4a and 4b are arranged so as to have substantially the same width as any of the above, to form the clad portion 2. This means that by arranging the pores 4a and 4b so that the clad portion 2 has a square cross section, the polarization plane to be held is displayed. The manufacturing method is also the same as in the first embodiment.

-Other Embodiments- The above embodiments are examples, and the present invention is not limited to these examples. The structure for exhibiting the polarization maintaining function may be the structure shown in FIG. 8 or 9. In FIG. 8, among the six pores 4 a and 4 b adjacent to the core 1, the other four pores 4 b have a larger diameter than the pair of pores 4 a facing each other with the core 1 in between. Around these, a large number of small-diameter pores 4a are arranged in a crystalline form to form a clad portion 2. Figure 9
The diameter of the core 1 is different in two directions orthogonal to each other, and the polarization maintaining function is exhibited. The ratio of the diameters of the core 1 is such that the length is 2 in the figure and the width is 1 in the figure.
A large number of small pores 4a are arranged in a crystalline form,
It has become. Further, the structure is not limited to the above, and any structure may be used as long as it has a polarization maintaining function.

The constituent material of the fiber 10 may be glass other than quartz glass, plastic, or the like, or may be glass obtained by doping quartz glass with Ge, B, F or the like.
The pores in the clad portion 2 may be arranged regularly such that the smallest unit is a square, a rectangle, or a honeycomb structure. The shapes of the pores 4a and 4b may be circular, elliptical, polygonal, semicircular, or any other shape. Clad part 2
The diameters of the small-diameter pores 4a constituting the above may all be the same or may be different. Also, G only for core 1
e, B, F, etc. may be doped. Pores may be provided in the core 1, or the core 1 may be voids.

The cross-sectional outer shape of the clad portion 2 is also the fiber 10
If the maximum width or the minimum width of the clad portion 2 observed from the side of the fiber 10 when rotated about the central axis is such that it appears every rotation of 180 degrees or 90 degrees, Any shape is acceptable. In addition, the width of the clad portion 2 observed from the side of the fiber 10 also depends on the pores 4.
Other than a, for example, quartz may be formed of a substance having a different refractive index.

Further, the pores 4a and 4b of the clad portion 2 may be filled with a material other than silica glass, for example, glass or polymer of another type, silica glass doped with Ge, B, F or the like. . The method of manufacturing the fiber also uses the pores 4a, 4
All or part of b may be opened with a drill or the like.

[0044]

The present invention is carried out in the form as described above, and has the following effects.

When the polarization-maintaining photonic crystal fiber 10 is rotated around the central axis, either the maximum width or the minimum width of the cladding portion 2 observed from the side of the fiber 10 is rotated by 90 degrees or 180 degrees. Since it appears every time the polarization plane is held, the polarization plane to be held can be easily discriminated by observing from the side of the fiber 10, and the polarization plane alignment work can be easily performed in a short time when splicing with another polarization holding fiber. The working cost can be reduced. In particular, in the case where either the maximum width or the minimum width appears every 180 degrees, two orthogonal polarization planes can be distinguished and distinguished. Moreover, since the manufacturing is easy, the manufacturing cost can be reduced.

[Brief description of drawings]

FIG. 1A is an end view of a polarization-maintaining photonic crystal fiber according to a first embodiment, FIG. 1B is a schematic view of the end surface, and FIG. 1C is a width of a clad portion viewed from the side of the fiber and the fiber. It is a relationship diagram with a rotation angle.

FIG. 2A is a schematic view of an end face of a polarization-maintaining photonic crystal fiber according to a second embodiment, and FIG. 2B is a relationship diagram between a width of a clad portion viewed from the side of the fiber and a fiber rotation angle. is there.

FIG. 3A is a schematic view of an end face of a polarization-maintaining photonic crystal fiber according to a third embodiment, and FIG. 3B is a relationship diagram between the width of the cladding and the fiber rotation angle as viewed from the side of the fiber. is there.

FIG. 4A is a schematic view of an end face of a polarization-maintaining photonic crystal fiber according to a fourth embodiment, and FIG. 4B is a relationship diagram between the width of a clad portion viewed from the side of the fiber and the fiber rotation angle. is there.

FIG. 5A is a schematic view of an end face of a polarization-maintaining photonic crystal fiber of a fifth embodiment, and FIG. 5B is a relationship diagram of the width of the clad portion viewed from the side of the fiber and the rotation angle of the fiber. is there.

FIG. 6A is a schematic view of an end face of a polarization-maintaining photonic crystal fiber of a sixth embodiment, and FIG. 6B is a relationship diagram of the width of the clad portion viewed from the side of the fiber and the rotation angle of the fiber. is there.

FIG. 7A is a schematic view of an end face of a polarization-maintaining photonic crystal fiber of a seventh embodiment, and FIG. 7B is a relationship diagram between a width of a cladding portion and a fiber rotation angle viewed from the side of the fiber. is there.

FIG. 8 is a diagram of another structure having a polarization maintaining function.

FIG. 9 is a diagram of yet another structure having a polarization maintaining function.

10A is an end view of a conventional polarization-maintaining photonic crystal fiber, FIG. 10B is a schematic view of the end face, and FIG.
[Fig. 3] is a relationship diagram of the width of the clad portion viewed from the side of the fiber and the rotation angle of the fiber.

[Explanation of symbols]

1 core 2 Clad part 3 Overclad part 4a, 4b pores 10 Polarization-maintaining photonic crystal fiber 20 Polarization-maintaining photonic crystal fiber

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Shinya Yamatori             4-3 Ikejiri, Itami City, Hyogo Prefecture Mitsubishi Electric Cable             Industrial Co., Ltd. Itami Works (72) Inventor Moriyuki Fujita             4-3 Ikejiri, Itami City, Hyogo Prefecture Mitsubishi Electric Cable             Industrial Co., Ltd. Itami Works (72) Inventor Satoru Kawanishi             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation (72) Inventor Kazunori Suzuki             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation (72) Inventor Hirokazu Kubota             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation F-term (reference) 2H050 AB04 AC42 AC53 AC62

Claims (2)

[Claims] 1. A polarization-maintaining device comprising a clad part around which a large number of pores extending in the axial direction of the optical fiber are arranged in a crystalline form, and an over-clad part provided around the clad part. A photonic crystal fiber, the width of the clad portion observed from the side of the fiber is changed by rotation around the central axis of the fiber,
When the fiber is rotated around the central axis from the position where either the maximum width or the minimum width of the clad portion is observed, the clad portion is rotated when the rotation angle is larger than 0 degree and smaller than 180 degree. The pores are smaller than the maximum width at the angle of 0 degrees or larger than the minimum width, and when the rotation angle becomes 180 degrees, the pores have a width substantially the same as either the maximum width or the minimum width at the rotation angle of 0 degrees. A polarization-maintaining photonic crystal fiber, which is configured to display a polarization plane to be held by being arranged. 2. A polarization-maintaining device comprising: a clad part in which a large number of pores extending in the optical fiber axial direction are arranged in a crystalline form around a core; and an over-clad part provided around the clad part. A photonic crystal fiber, the width of the clad portion observed from the side of the fiber is changed by rotation around the central axis of the fiber,
When the fiber is rotated around the central axis from the position where either the maximum width or the minimum width of the clad portion is observed, the clad portion is rotated when the rotation angle is larger than 0 degree and smaller than 90 degree. It is smaller than the maximum width at the angle of 0 degrees or larger than the minimum width, and when the rotation angle becomes 90 degrees, the pores are formed so as to have a width substantially equal to either the maximum width or the minimum width at the rotation angle of 0 degrees. A polarization-maintaining photonic crystal fiber, which is configured to display a polarization plane to be held by being arranged.