JPS63208809A - Polarization maintaining optical fiber - Google Patents

Abstract

PURPOSE:To easily identify the main axis direction of a polarization from outside and to easily select the inflection direction where deterioration of crosstalk is least by deciding the main axis direction of the external polarization from the shape of a coating. CONSTITUTION:A polarization optical fiber 5a has a core 1, stress inducing members 2, and a clad 3, the couple of strain inducing members 2 are arranged on both side parts, and they are integrated by the clad 3. Further, the sectional shape of a protective coating layer which covers its outer periphery is a long circle having its major axis on the prolongation of the line connecting the strain inducing parts, i.e. the main axis direction of light propagated in this polarization maintaining optical fiber. Consequently, the main axis direction of the polarization can be decided from its outer appearance and while the optical fiber is coiled while the bending direction of the optical fiber and the main axis direction of the polarization is held at the angle where the best crosstalk is obtained; and there is no deterioration of crosstalk with the bending direction and this is effective specially when used in a coil shape for an optical fiber gyroscope, etc.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to polarization maintaining optical fibers. More specifically, the present invention relates to the configuration of a novel polarization-maintaining optical fiber in which the principal axis direction of the polarized waves it maintains can be easily identified from the outside by giving its cross-sectional shape anisotropy.

Conventional technology Polarization-maintaining optical fibers are configured to provide a large difference in propagation coefficients for mutually orthogonal polarizations of light propagating through the core, so that substantially only a specific polarization of the propagating light is propagated. It is an optical fiber that has been

Several types of polarization-maintaining optical fiber structures have been developed. For example, by making the cross-sectional shape of the core rectangular or elliptical, or by making the cross-sectional shape of the cladding oval for a core with a circular cross-section, the core can be shaped in directions perpendicular to the propagation optical axis. configured to vary the applied physical stress. Such a configuration is called a stress birefringent fiber.

FIGS. 3 and 4 are cross-sectional views showing typical structures of stress-birefringent polarization-maintaining optical fibers.

The polarization-maintaining optical fiber shown in FIG. 3 is a so-called "panda fiber", in which a pair of stress applying members 2 are arranged at symmetrical positions around a core 1, and are further integrated by a cladding 3. At this time, the stress applying member 2 is made of a material with a higher coefficient of thermal expansion than the cladding 3, and in the completed panda fiber, the direction in which the stress applying members 2 are connected (hereinafter, this direction is referred to as the main axis direction) , a tensile stress is applied to the core 1. Therefore, the core 1 has a refractive index different in the direction of the stress and in a direction perpendicular to this direction, and the refractive index of each polarized wave of light propagating through the core 1 is different. A large difference in phase velocity occurs.

The polarization-maintaining optical fiber shown in FIG. 4 also has a pair of stress applying members 2 embedded in both sides of the core 1 and integrated by a cladding 3. Although the stress applying members have different shapes, It has similar functions.

Incidentally, these polarization-maintaining optical fibers are provided with a coating layer 4 for physical protection of the surface, similar to general optical fiber wires.

Further, the most typical characteristic representing the polarization maintaining performance of a polarization maintaining optical fiber is represented by the value of crosstalk between mutually perpendicular polarized waves.

That is, a single polarized light is input into a polarization-maintaining optical fiber, and at the output end, the power of the output light with the same polarization direction as that of the input light is Px, and the power of the output light with a polarization orthogonal to this light is p.
y, [crosstalk] = 10 log (Py/Px)
(This is a value obtained according to the formula dB. As can be seen from this formula, the smaller the crosstalk value is, the better the polarization maintaining characteristic is.

By the way, it is known that when the stress birefringent optical fiber as described above is bent, the bending direction affects the crosstalk characteristics.

Electronics Letters Vol. 19 No. 17, pages 679 to 680 (ELECTRONIC'S LBTTE)
R3Vol, 19 No.

17 pp. 679-680), it is reported that in the polarization maintaining optical fiber having the structure shown in FIG. 4, the crosstalk characteristics change depending on the bending direction with respect to the main axis direction. That is, with respect to the plane defined by the unbent polarization-maintaining optical fiber and the principal axis direction,
It is stated that the degree of deterioration of crosstalk characteristics due to bending varies greatly depending on the angle formed by the plane including the bent optical fiber.

The present inventors also confirmed that the polarization-maintaining optical fiber having the structure shown in FIG. 3 exhibits similar characteristics. Figure 5 (
a) is a graph showing the characteristics of a polarization-maintaining optical fiber actually measured by the inventor using the polarization-maintaining optical fiber having the shape shown in FIG. 3; That is, the diameter including the protective coating is 9
A polarization-maintaining optical fiber of 00 μm is wound around a cylindrical jig with a diameter of 5 Qmm, and as shown in Fig. The angle θ formed by the generatrix of the tool was varied, and the crosstalk characteristics in each case were measured and plotted.

Note that the crosstalk characteristics in FIG. 5(a) are relative values where ΔCT=OdB is the time when the crosstalk is at its best. Further, other specifications of the polarization maintaining optical fiber used are shown in Table 1.

As is clear from Table 1, FIG. 5(a), the crosstalk characteristics are best when the angle θ is 0° or 180'.

Problems to be Solved by the Invention By the way, one of the main uses of polarization-maintaining optical fiber is as a coil for an optical fiber gyro. It goes without saying that the polarization-maintaining optical fiber is bent when forming a coil, and therefore, if the main axis direction of the polarization-maintaining optical fiber can be kept parallel to the generatrix of the jig when producing the coil, An optical fiber gyro coil with extremely excellent crosstalk characteristics can be created.

However, as shown in FIG. 4 and the cross section shown in FIG. 4, the conventional polarization-maintaining optical fiber is entirely covered isotropically with a coating 4, and except for the end face, the main axis direction cannot be viewed from the outside. I couldn't find out.

In other words, when manufacturing a coil using conventional polarization-maintaining optical fiber, it is impossible to wind the optical fiber while maintaining the bending direction and the main axis direction so that the crosstalk is at its best, and the crosstalk deteriorates quickly. was inviting. In addition, such a problem always occurs in other applications as well, when the polarization-maintaining optical fiber must be bent due to design requirements.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a novel polarization-maintaining light whose principal axis direction can be easily identified from the outside, and whose bending direction can easily select the bending direction that causes the least deterioration of crosstalk when bending. The aim is to provide fiber.

Means for solving the problem, that is, according to the present invention, a core, two stress applying members arranged in parallel on both sides of the core, a cladding in which the core and the stress applying members are embedded and held; A polarization-maintaining optical fiber comprising a protective coating surrounding the outer periphery of the cladding and configured to selectively propagate only a specific polarized wave of propagating light, the protective coating having a cross-sectional shape perpendicular to the propagation optical axis. There is provided a polarization-maintaining optical fiber characterized in that it is provided with anisotropy so that the principal axis direction of a specific polarized wave propagating through the core can be identified from the outside.

Here, the cross-sectional shape of the polarization-maintaining optical fiber includes ellipsoids, rectangles, etc., but especially when considering the case where the optical fiber is wound around a jig to form a coil, the dimension in the main axis direction is more A long cross-sectional shape is desirable.

Additionally, in the case of stress-birefringent polarization-maintaining optical fibers, the stress-applying section generally applies tensile stress to the core, so it may be due to the shape or deformation of the protective coating layer when bent. A shape that presses the core and cancels out this tensile stress is not preferred.

The polarized optical fiber of the present invention is configured such that the direction of the principal axis of polarized waves can be determined from its appearance depending on the shape of its coating. Therefore, the direction of the main axis of polarization held by the polarization-maintaining optical fiber can be easily identified over its entire length.

In this way, for example, when a polarization-maintaining optical fiber is wound into a coil, deterioration of crosstalk characteristics due to a difference in the bending direction of the polarization-maintaining optical fiber can be prevented to the utmost.

EXAMPLES The present invention will be described in more detail below with reference to the accompanying drawings, but what is shown below is only one example of the present invention, and does not limit the technical scope of the present invention in any way. isn't it.

FIG. 1(a) is a cross-sectional view showing the shape of a polarization-maintaining optical fiber according to the present invention.

As shown in the figure, the polarized optical fiber 5a of the present invention has the same structure of the core 1, stress applying member 2, and cladding 3 as the conventional polarization-maintaining optical fiber.

That is, a pair of stress applying members 2 are arranged on both sides of the core 1, and these members are made into one body by the cladding 3.

However, the cross-sectional shape of the protective coating layer that covers the outer periphery is different from that of conventional ones, and the long axis is an extension of the line connecting the stress applying members, that is, the main axis direction of the light propagating in this polarization-maintaining optical fiber. It has an oval shape.

The production of such a polarization-maintaining optical fiber was carried out using a conventional drawing machine equipped with an elliptical die on the output side, according to conventional procedures. However, care was taken at the stage of setting up the apparatus and supplying the preforms so that the major axis of the elliptical die on the exit side was on the arrangement plane of the core 1 and the stress applying member 2, that is, on the extension of the main axis. This operation was performed by checking with the naked eye, but when the cross section of the actually drawn optical fiber was observed under a microscope, the main axis direction of the fiber and the long axis direction of the ellipse of the coating matched as designed.

The produced polarization-maintaining optical fiber 5a has a major diameter of 30 μm compared to an optical fiber having a cladding with a diameter of 125 μm.
The length of 0 μm and 1 minor axis was 200 μm.

For comparison, the above optical fiber 5 was also
A polarization-maintaining optical fiber 5b was fabricated, which differs from the fiber a in only the cross-sectional shape of the coating layer 4 and has the same other characteristics. This polarization-maintaining optical fiber 5b again had a diameter of 300 μm with a cladding having a diameter of 125 μm.

Two types of polarization maintaining optical fibers 5as5b thus completed
Two types of polarization-maintaining optical fiber coils were made by separately winding 100 m of each coil around two mandrels 6 with a diameter of 5 Q mm.

FIG. 2 is a diagram showing how the polarization-maintaining optical fiber 5a is wound around the mandrel 6 in a coil shape. so that it is perpendicular to the surface of

The crosstalk of the two polarization-maintaining optical fiber coils fabricated in this way was measured using a light source with a wavelength of 1.3 μm, and the result was -13.7 dB for the one using optical fiber 5b.
The one using optical 7 fiber 5a is -19.8 dB,
Optical fiber 5a which is a polarization maintaining optical fiber according to the present invention
It was confirmed that the crosstalk of the coil using the conventional optical fiber 5b was 6.1 dB better than that of the coil using the conventional optical fiber 5b.

It is also preferable to provide a flat portion on the surface of the coating layer 4 by contacting it with a roller or the like before hardening, as shown in FIG. Particularly when the optical fiber is wound around a mandrel as described above, this flat portion makes the angle of the optical fiber on the mandrel more stable.

As described in detail of the invention, in the polarization-maintaining optical fiber according to the present invention, the direction of the principal axis of polarization can be determined from its appearance, and the angle formed between the bending direction of the optical fiber and the direction of the principal axis of polarization can be determined from the appearance. can be wound into a coil while maintaining the angle that provides the best crosstalk. Therefore, there is no crosstalk deterioration due to the bending direction, which is particularly effective when a polarization-maintaining optical fiber is used in a coiled form in an optical fiber gyro or the like.

[Brief explanation of the drawing]

FIGS. 1(a) and 1(a) are cross-sectional views showing the configuration of a polarization-maintaining optical fiber according to the present invention, and FIG. 2 shows how the polarization-maintaining optical fiber 5a is wound around a mandrel 6 in a coil shape. FIG. 3 is a cross-sectional view showing the configuration of a conventional polarization-maintaining optical fiber, and FIG. 4 is a cross-sectional view showing the configuration of another conventional polarization-maintaining optical fiber. Yes, Figure 5(a) shows the angle θ between the bending direction of the polarization-maintaining optical fiber and the principal axis direction of polarization, and the crosstalk degradation ΔCT.
FIG. 5(b) is a graph showing the relationship between
a) It is a diagram explaining the angle θ shown in the figure. (Main reference numbers) ■...Core, 2...Stress applying part, 3...Clad, 4...Coating, 5a, b...Polarization maintaining optical fiber , 6...φ... mandrel

Claims (3)

[Claims] (1) A core, two stress applying members arranged in parallel on both sides of the core, a cladding in which the core and stress applying members are embedded and held, and a protective coating surrounding the outer periphery of the cladding. , a polarization-maintaining optical fiber configured to selectively propagate only a specific polarized wave of propagating light, wherein a cross-sectional shape of the protective coating perpendicular to the propagation optical axis is configured to selectively propagate only a specific polarized wave of propagating light; A polarization-maintaining optical fiber characterized by being anisotropic so that its principal axis direction can be identified from the outside. (2) The polarization-maintaining optical fiber according to claim 1, wherein the cross-sectional shape of the protective coating is an ellipse whose major axis is in the direction of the main axis. (3) The polarization-maintaining optical fiber according to claim 1 or 2, wherein a flat portion parallel to the main axis direction is formed on the surface of the protective coating.