KR100481422B1 - Polarization insensitive tunable optical fiber gratings - Google Patents

Abstract

Disclosed is a polarization mode distributed compensation fiber grating variable device. The present invention is a concave-convex plate having a grating groove for forming a grating in the optical fiber, a coupling means and a through hole through which the optical fiber is inserted in the center of the outer peripheral surface is formed, the pressing portion is formed in the insertion groove in which the uneven plate is seated; An inner side is coupled with the coupling means, and an outer circumferential surface is formed with a fastening means for rotation, the fastening portion corresponding to the fastening means on the upper portion of the disc to engage with the fastening portion coupled to the crimping portion and the fastening means formed on the outer peripheral surface of the fastening portion. Means are formed, characterized in that consisting of a rotating portion rotated about the central axis of the disc.

According to the present invention, it is easy to manufacture with a simple configuration of the concave-convex plate and the pressing means, small production, it is possible to reduce the manufacturing cost, it is possible to change the transmission spectrum and refractive index of the optical fiber grid by rotating the concave-convex plate, Because it eliminates the polarization mode dispersion phenomenon, it can be used as a part of optical communication and optical devices such as various sensors and filters without polarization dependency.

Description

Polarization mode distributed compensated optical fiber gratings {Polarization insensitive tunable optical fiber gratings}

The present invention relates to a polarization mode dispersion compensation optical fiber grating variable device, in particular to press the pressure at the same time when pressing the optical fiber in the two pressing parts in the direction perpendicular to each other in order to eliminate the birefringence phenomenon that occurs when pressing the optical fiber In addition, the present invention relates to a polarization mode distributed compensation fiber grating variable device manufactured to apply the same pressure to both sides when adjusting the applied pressure.

In general, the optical fiber grating has been developed to the extent that it can be applied to various fields such as various filters, sensors, dispersion compensators, mode converters and so on in the application. These optical fiber gratings are classified into short or long period optical fiber gratings according to their periods. The double long period optical fiber gratings have a high order (cladding) mode in the same direction as the propagation direction of a specific wavelength of light with a period of several hundred μm. It uses the principle of combining and attenuating.

The fabrication of such long-period fiber gratings generally involves exposing an optical fiber to an ultraviolet laser and inducing a refractive index change by applying pressure to the optical fiber. The method of inducing the refractive index change by applying pressure to the optical fiber is composed of an uneven plate and a pressing means formed with a grating groove on the optical fiber splicing surface, which has recently been reduced in manufacturing cost, manufacturing time, overcoming limitations of the variable wavelength region, and centering. An optical fiber grating variable device having characteristics such as precise control of wavelength has been developed.

However, such an optical fiber lattice variable device has a disadvantage in that the birefringence effect is caused by the difference in refractive index in the direction of the pressing direction and the direction perpendicular to the method by pressing the optical fiber when manufacturing the optical fiber grid. For this reason, the polarization mode dispersion prevention optical fiber lattice device has been proposed among the efforts to cancel the polarization mode dispersion by canceling the refractive index difference due to the pressing in the manufacturing, but the existing invention (domestic patent 10-2001-47063) When pressing the optical fiber in two pressing portions in the vertical direction, it is not possible to apply the pressing at the same time, but must be applied sequentially one by one, and there is a point that it is difficult to apply the same pressure to both sides when adjusting the applied pressure.

Accordingly, an object of the present invention is to press the two pressing parts at the same time when pressing the optical fiber, and to apply the same pressure on both sides when adjusting the pressure applied to form a thread in the pressing section to have a reliability for the transmission spectrum The present invention provides a polarization mode distributed compensation fiber grating variable device capable of simultaneously applying pressure by controlling both sides at the same time.

Polarization mode distributed compensation optical fiber grid variable device for achieving the above object of the present invention, the grating groove is formed on the contact surface seated on the optical fiber to form a grating by the pressing force when the optical fiber is pressed, and in the columnar shape, Coupling means is formed on the outer peripheral surface, a through hole for inserting the optical fiber in the longitudinal direction in the center is formed, the crimping portion formed with at least two insertion grooves are formed so that the grating groove of the uneven plate is seated on one surface of the optical fiber, pair The through-hole is formed to face each other, the through-hole is formed so that the optical fiber is penetrated, the inner side is coupled to the crimping portion by the coupling means corresponding to the coupling means, the fastening means for each rotation on the outer peripheral surface It is formed in the tightening portion and the outer peripheral surface of the tightening portion is closer to each other by coupling with the pressing member in accordance with each rotation A fastening means corresponding to the fastening means is formed in the upper portion of the disk to engage with the fastening means formed to include a rotating portion that is rotated about the central axis of the disc.

The pressing part is divided into two horizontally together with the through hole, and a horizontal lower pressing member connected to one side by a hinge so as to be close to each other, and a horizontal upper pressing member having an insertion groove formed on a cutting surface thereof, which are rotated 90 degrees in pairs. As the vertical lower pressing member and the vertical upper pressing member are formed in the state and are respectively close by the hinge, the uneven plate seated in the insertion groove is pressed onto the optical fiber, and the horizontal lower pressing member and the vertical lower pressing member are integrated or horizontally. The upper pressing member and the vertical upper pressing member may be integrated, and a fixing piece should be provided to fix the pressing portion by using a known fixing means at one end of the vertical upper pressing member, and one side of the outer circumferential surface is a screw coupling means. It would be desirable to screw in from.

On the other hand, the tightening portion is configured to be screwed on the inside is characterized in that the separation distance from each other is changed according to the coupling with the crimping portion, each of the fastening means of the gear-shaped protruding member on the outer peripheral surface so as to be rotatable It is preferable to be formed to be geared from the outside.

On the other hand, it is preferable that the rotating part is formed on the upper portion of the disc so that the protruding member and the gear bite along the outer circumferential surface so that the tightening portion is rotated opposite to each other when the disc is rotated.

On the other hand, the uneven plate is inserted into both sides of the pressing portion perpendicular to each other, have the same lattice period, the sum of the lengths of the lattice adjacent to each other among the lattice formed by the two uneven plate is the period of the grating groove ( Half of) / 2) is preferred. The depth of the grating groove (d1) is formed in the range of 5㎛ to 10㎛, the width of the grating groove (d2) is formed in the range of 5㎛ to 50㎛, not only characterized in that the grating groove is periodic or aperiodic . At least one grating groove having different depths d1 and width d2 is formed, gratings having the same grating grooves are grouped, or different gratings are formed in combination.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

1 is a view showing the basic principle for implementing a polarization mode distributed compensation fiber grating variable device of the present invention. Referring to Figure 1, the polarization mode dispersion compensation optical fiber grating variable device of the present invention is a concave-convex plate formed a lattice groove on the bonding surface of the optical fiber (1) to form a grating by the pressing force when the optical fiber (1) pressing 3, 3 ', and the crimping | compression-bonding part 2 comprised from the support plates 4 and 4' which hold | maintain and hold | maintain the said optical fiber 1. As a feature of the present invention, there is provided at least one crimping portion 2 composed of the uneven plates 3 and 3 'and the support plates 4 and 4'. Accordingly, by pressing in the direction perpendicular to the pressing direction or in a predetermined angular direction to perform a function to eliminate the polarization mode dispersion phenomenon that may be caused by the pressing. The gratings formed on these uneven plates 3 and 3 'may be periodic or aperiodic.

In the present embodiment, it is proposed to press the uneven plate (3, 3 '), but in some cases, it is possible to press the supporting plate (4, 4') or both. In addition, the support plates 4 and 4 'may not be installed if there is an area where the optical fiber is fixedly supported.

2 is a view showing a phenomenon in which an average value of birefringence is canceled or polarization mode dispersion is compensated for in an optical fiber according to the present invention. Referring to FIG. 2, a fast axis exists in the direction in which the first part is pressed in the upper part of the optical fiber 1 and the second part is pressed in the direction perpendicular to the optical fiber 1, respectively, in the direction perpendicular thereto. You can see that there is a slow axis. However, as in the present invention, if the same pressure is applied to these two parts at the same time, the fast axis in the first part and the slow axis in the second part meet, and the slow axis in the first part and the second part as well. When the fast axis meets, birefringence is canceled, or polarization mode dispersion is compensated.

3 is a view showing a polarization mode distributed compensation optical fiber grating variable device according to the prior art. Referring to Figure 3, the conventional polarization mode distributed compensation fiber grating variable device is provided with a pressing member 40 for applying a pressure to the optical fiber, it can interpolate the pressing member 40, the penetration through the optical fiber It consists large of the frame 50 in which the ball 41 was formed.

The pressing member 40 is coupled to the uneven plate 10, the rotating member 42 for rotating the uneven plate 10, the pressure screw 44 for pressing the uneven plate 10 and the, When pressing the uneven plate 10 by the pressure screw 44 between the pressure screw 44 and the uneven plate 10 to reduce the contact resistance with the uneven plate 10 due to the rotation of the pressure screw 44. It consists of a metal ball 46 provided in the. The pressing member 40 is provided with at least one so that the pressing member 40 can be pressed in the vertical or constant angular direction in all the regions not pressed along the optical fiber axial direction.

In addition, the spring between the pressure screw 44 and the uneven plate 10 serves as a cushioning material for buffering the degree of pressure transmitted to the uneven plate 10 when pressing the pressure screw 44, the pressure screw ( In the case of releasing 44, it functions to return the uneven plate 10 pressed by the pressure to its original position. In addition, the metal ball 46 is a function that receives the rotational force by the screw to the vertical area and transmits it as a vertical force, it may not be necessary if the frictional force between the uneven plate 10 and the pressure screw 44 does not significantly act.

Conventional polarization mode dispersion compensation optical fiber grating variable device formed as described above is not able to give a sufficiently large pressure, because the pressure screw 44 is used when pressing the uneven plate 10, two yaw in the direction perpendicular to each other The steel plate 10 is made to be difficult to press at the same time. In addition, when adjusting the magnitude of the pressure applied to the uneven plate 10, it is difficult to apply the same pressure to both sides by adjusting the pressure screw 44. This is a problem in the experimental purpose to eliminate the polarization mode dispersion phenomenon by applying the same pressure to the two pressing portions in the direction perpendicular to each other.

4 is a view showing a polarization mode dispersion compensation optical fiber grating variable device according to an embodiment of the present invention. Referring to Figure 4, in the embodiment of the present invention is roughly divided into the concave-convex plate (500, 501) and the pressing portion 100, the fastening portion 200 and the rotating portion 300 in the direction perpendicular to each other.

The uneven plates 500 and 501 form a lattice directly on the optical fiber 1, and when the optical fiber 1 is pressed, a lattice groove is formed on a contact surface seated on the optical fiber 1 so that at least one lattice is formed by a pressing force. The formed concave-convex plates 500 and 501 will be described in detail with reference to FIGS. 5, 6, and 7 below.

The crimping part 100 has a screw thread formed at one side of the outer circumferential surface of the cylindrical outer circumferential surface to be screwed to the outer circumferential surface having a predetermined length, and a hooking jaw 117 is formed at the end portion of the thread on the cylindrical outer circumferential surface, and the optical fiber is formed in the longitudinal direction. The through hole 126 is formed to penetrate.

At this time, the cylinder is divided into two parts along the through-hole 126 in the horizontal direction is divided into a horizontal lower pressing member 110 and a horizontal upper pressing member 112, the thread of the outer peripheral surface is formed, the screw bone is relatively shallow toward the inside It will be apparent that the uneven plate (500, 501) is capable of crimping the optical fiber is formed, the hinge is formed on the other side is formed by the horizontal lower pressing member 110 and the horizontal upper pressing member 112 is hinged to each other. .

On the other hand, the insertion surface 118 is formed on the cutting surface of the horizontal upper pressing member 112 so that the upper side of the horizontal concave-convex plate 500 is inserted.

On the other hand, it is formed to face the horizontal lower pressing member 110 and the horizontal upper pressing member 112, the vertical lower pressing member 122 and the vertical upper pressing member 120 rotated by 90 degrees is formed.

In this case, a through hole 126 is formed to penetrate the optical fiber 1, and an insertion groove 128 is formed on one surface of the vertical lower compression member 122 so that the vertical uneven plate 501 is inserted therein. It will be apparent that the hinge 124 is formed on the other side of the thread formed on the outer peripheral surface of the 122 and the vertical upper pressing member 120.

On the other hand, the horizontal lower pressing member 110 and the vertical lower pressing member 122 is compressed and fixed, or the horizontal upper pressing member 112 and the vertical upper pressing member 120 are pressed and fixed, and the horizontal The fixing piece 130 is formed at one end of the upper compression member 112 or the horizontal lower compression member 110 and the vertical upper compression member 120 or the vertical lower compression member 122 that is fixed and fixed, but not known. It is fixed by the means serves to prevent the two uneven plate (500, 501) shake when pressing the optical fiber (1).

The fastening part 200 is formed with a cylinder having a predetermined length, a through hole 202 is formed so that the optical fiber 1 penetrates the cylinder in the longitudinal direction, one side of the horizontal lower pressing member 110 and A screw bone is formed inwardly so as to be screwed with a screw thread formed on an outer circumferential surface of the horizontal upper pressing member 112, and a protruding member 206 is formed along the outer circumferential surface of the cylinder so as to be rotatable by an external force.

On the other hand, it is formed so as to face the cylinder, the screw bone 210 is formed inward so as to be screwed with the thread formed on the outer peripheral surface of the vertical lower compression member 122 and the vertical upper compression member 120, the optical fiber 1 is penetrated The protruding member 206 is also formed in the through hole 202 and the outer circumferential surface thereof.

The rotating part 300 is coupled to the engaging bone 208 formed by the protruding member 206 formed on the outer circumferential surface of the two fastening members 200 along the outer circumferential surface of the circular disk 302 protruding piece so as to rotate. 304 is formed.

In addition, the rotation axis of the rotation center of the disc 302 is formed to be rotated by an external force.

Although not shown in order to rotate the rotating shaft 306, it is preferable to set a predetermined pressure with a device such as a torque wrench to enable rotation up to a set pressure.

At this time, the rotation shaft 306 is rotated and at the same time the protrusion piece 304 is rotated relative to the disc 302, when rotating the protrusion pieces 304 on both sides of the fastening portion 200 of the fastener 200 This interlocking rotation would be possible.

In the optical fiber grid variable device formed as described above, the optical fiber 1 is inserted into the through hole 126 formed in the fastening part 200, and the uneven plates 500 and 501 are placed on both end surfaces thereof, and then the hinges 114, 124 by the horizontal upper pressing member 112 and the vertical upper pressing member 120 abuts the horizontal lower pressing member 110 and the vertical lower pressing member 122, respectively, the upper portion of the uneven plate (500, 501) Is inserted into both insertion grooves (118, 128).

At this time, the fixing piece 130 formed on the vertical upper compression member 120 is fixed using an external fixing device, and at this time, up to the screw bone 210 formed inside the fastening part 200 into which the optical fiber 1 is inserted. When the tightening unit 200 is inserted, the locking jaw 204 formed inside the tightening unit 200 enters, and when the screw bone 210 reaches the starting portion, the fastening unit 100 is formed. It stops at the locking jaw 117 formed at the end of the screw bone.

At this time, one side of the protruding piece (304) formed on the rotating part (300) is placed on both sides of the crimping portion (100) on the catching bone (208) formed on the protruding member (206) formed on the outer circumferential surface of the tightening part (100). When the rotating unit 300 is rotated by using a device such as a torque wrench, the protruding pieces rotate in the circumferential direction, and thus both side fastening members rotate in opposite directions to each other, and thus the crimping unit 100 is rotated. As the tightening part 200 and the crimping part 100 are screwed along the thread formed on the outer circumferential surface of the screw, the screw bone becomes shallower toward the inner side formed in the crimping part 100, so the strength of the pressure that is pressed during the screwing gradually increases. Become strong. Also. When the fastening part 200 and the crimping part 100 are screwed together, the two fastening members have the same rotational force by the same rotational force, so that the pressure applied to the uneven plates 500 and 501 is increased. Both sides become the same, and eventually the grating is formed by grating grooves formed in the uneven plates 500 and 501 on the surface of the optical fiber 1.

In this figure, although the protruding member and the protruding piece have a rectangular shape, it will be obvious that the deformable shape is adapted to the bite of the gear.

5A and 5B are diagrams showing a relationship between two uneven plates and uneven plates having the same phase matching condition according to an embodiment of the present invention. Referring to FIG. 5, since the phase shift may occur depending on the distance between the two uneven plate 510 and the uneven plate 510 ′, the two uneven plate 510 and the uneven plate 510 ′ come into contact with each other. In the case of Fig. 5a in which the grid engraved in the part is concave, d1 + d2 It is preferable to set it as / 2. Similarly, even in the case of FIG. 5B in which the lattice engraved at the portion where the uneven plate 520 and the uneven plate 520 'are in contact is convex, d3 + d4 = It would be desirable to do as much as / 2.

6A and 6B are perspective views illustrating opposing surfaces of a support plate and an uneven plate according to an embodiment of the present invention. Referring to FIG. 6, the support plate 540 forms the fixing groove 541 on one surface, and the uneven plate 530 forms the V groove 531 on one surface. At this time, the fixing groove 541 only serves to prevent the movement of the optical fiber 1, it is not necessary to form the fixing groove 541 to prevent the acting as a hindering element of the grid formation.

7A and 7B are views showing a modification of the uneven plate according to the embodiment of the present invention. Referring to FIG. 7, the V-groove has a certain interval, that is, a certain period ( It is also possible to manufacture the concave-convex plate 550 formed with a), and can be used to produce a concave-convex plate 560 with a randomly modified interval. In addition, although the V-groove is formed in one direction, it can be applied in various forms, such as a cross-section having an arbitrary angle, a plurality of V-grooves have a random angle with respect to one V-groove, and the like. have. In addition, the V groove may be adjusted at the time of manufacturing the V groove depth d1 to adjust the degree of loss of the higher order mode. This V-groove depth d1 uses the value set in the range of about 5 micrometers-10 mm. Of course, the characteristics of the filter required by the gain flat filter and the bandpass filter to be used will be required. And it is preferable that the width | variety d2 of a V groove | channel is set in the range of 5 micrometers-50 mm. At this time, by adjusting the width d2 of the V-groove and the portion d3 other than the V-groove region, the region for pressing the optical fiber 1 and the region for not pressing can be arbitrarily adjusted. That is, pressure having a regular or irregular arrangement may be applied to the optical fiber 1, and even in the region to which the pressure is applied, an area not pressurized by adjusting the width d2 of the V groove can be formed. In the formation of the lattice, the lattice n1 of the V-groove region and the lattice n2 of the region other than the V-groove can be formed in a group form or in a combination form. That is, as shown in FIGS. 8A and 8B, in the case of a group form, lattice can be formed by n1, n1, n1, n1, n2, n2, n2, n2, and in the case of a combination form, n1, n2, n1, A lattice can also be formed by n2, n1, n2, n1, n2. Although only two types of gratings n1 and n2 have been described herein, the gratings may be formed in a group form and a combination form with any number of gratings. Predetermined spacing may be formed between groups of grids.

In addition, a certain period of time that the V groove is formed while maintaining the depth and width of the V groove constant ( The shorter the value of), the more the portion applied to the optical fiber 1 proceeds from the concept of plane to the concept of line. At this time, when pressing against the optical fiber 1 in the concept of the line can damage the optical fiber, it is also possible to round the pressing portion.

In addition, the V-groove may be formed with a square groove, or a semi-circular groove may be formed. Of course, in this case as well, the edges of the portions in contact with the optical fiber 1 may be rounded.

The uneven plates 550 and 560 have a disc shape as shown in the figure, but the concave-convex plates 550 and 560 may be manufactured in various shapes such as polygons, circles, etc. without being limited thereto. In addition, even in the surface where the V-groove is formed, it can be formed on both the upper surface and the bottom surface. That is, it means that the uneven plate (550, 560) formed with the different V-shaped grooves can be variously applied if necessary.

8A and 8B illustrate an optical fiber according to an embodiment of the present invention. It is a figure which shows schematically the refractive index formed in the space | interval. Referring to Figure 8, a certain period The optical fiber 1 'and an arbitrary angle when the V groove traveling direction formed on the uneven plate formed at intervals and the optical fiber traveling direction are pressed in a vertical state. Grating spacing to the optical fiber 30 ' or '(= / cos The refractive index is repeated with n ₁ , n ₂ , n ₁ , n _2, etc., thereby realizing an optical fiber grating having desired filter characteristics. Here, in forming the grating, the uneven plate having a predetermined angle, for example, 90 degrees with respect to the optical fiber axis may be manufactured, thereby achieving mass production and ease of manufacture. However, it would be desirable to rotate the uneven plate to produce an optical fiber filter suitable for the desired filter characteristics.

As described above, the polarization mode distributed compensation optical fiber grating variable apparatus according to the present invention can apply the same pressure to the two uneven plate in the direction perpendicular to each other and at the same time, it is manufactured with a simple configuration of the uneven plate and the pressing means Not only is this easy, there is an effect such as small production, manufacturing cost reduction. In addition, it is possible to change the transmission spectrum and refractive index of the optical fiber grating by eliminating the polarization mode dispersion phenomenon caused by the birefringence caused by the compression.It is easy to use in optical communication and optical device parts such as various sensors and filters without polarization dependency. Can be used.

The present invention is not limited to the above-described embodiments, and it will be apparent that many modifications are possible by those skilled in the art within the technical spirit of the present invention.

1 is a view showing the basic principle for implementing a polarization mode distributed compensation fiber grating variable device of the present invention.

2 is a view showing a phenomenon in which an average value of birefringence is canceled or polarization mode dispersion is compensated for in an optical fiber according to the present invention.

Figure 3 is a view showing a polarization mode distributed compensation fiber grating variable device according to the prior art.

4 is a view showing a polarization mode distributed compensation optical fiber grating variable device according to an embodiment of the present invention.

5A and 5B are views showing a relationship between two uneven plates and uneven plates having the same phase matching condition according to an embodiment of the present invention.

6A and 6B are perspective views illustrating opposing surfaces of a support plate and an uneven plate according to an embodiment of the present invention.

7A and 7B are views showing a modification of the uneven plate according to the embodiment of the present invention.

8A and 8B illustrate an optical fiber according to an embodiment of the present invention. A diagrammatic representation of refractive indices formed at intervals.

Explanation of symbols on the main parts of the drawings

1: optical fiber 100: crimp

110: horizontal lower pressing member 112: horizontal upper pressing member

114: hinge 117: locking jaw

118: insertion groove 120: vertical upper compression member

122: vertical lower compression member 124: hinge

126: through hole 200: tightening part

202: through hole 204: locking jaw

206: protruding member 208: locking bone

210: screw bone 300: rotating part

302: disc 304: protrusion

306: axis of rotation 500: horizontal uneven plate

501 vertical irregularities

Claims (14)

An uneven plate having a lattice groove formed on a contact surface seated on the optical fiber so as to form a lattice by pressing force when the optical fiber is pressed; In the columnar shape, a coupling means is formed on the outer circumferential surface thereof, and a through hole for inserting the optical fiber in the longitudinal direction is formed in the center thereof, and at least two insertion grooves are formed so that the lattice groove of the uneven plate is seated on one surface of the optical fiber. part; Paired columnar shapes are opposed to each other, the through-hole is formed so that the optical fiber penetrates, the inner side is coupled to the crimping portion by a coupling means corresponding to the coupling means, the outer peripheral surface fastening means for each rotation Tightening portion is formed is closer to each other by coupling with the pressing member according to each rotation; And A rotating part formed on an upper surface of the disc to be engaged with the fastening means formed on an outer circumferential surface of the tightening part, the fastening means corresponding to the fastening means being rotated about a central axis of the disc; Polarization mode distributed compensation fiber grating variable device, characterized in that made. The method of claim 1, wherein the crimping portion The horizontal lower pressing member which is divided into two horizontally together with the through hole and connected to one side by a hinge so as to be close to each other, and a horizontal upper pressing member having an insertion groove formed on a cutting surface thereof, is formed in pairs and rotated by 90 degrees. And a vertical lower pressing member and a vertical upper pressing member are formed so that the concave-convex plates seated in the insertion grooves are pressed onto the optical fiber as they are adjacent to each other by a hinge. The method of claim 2, wherein the crimping portion A polarization mode distributed compensation optical fiber grid variable device, characterized in that the horizontal lower compression member and the vertical lower compression member is integrated or the horizontal upper compression member and the vertical upper compression member are integrated. delete The said crimping part in any one of Claims 1-3. A polarization mode distributed compensation optical fiber grating variable device, characterized in that one side of the outer peripheral surface becomes a screw coupling means inclined the depth of the screw bone to increase the pressing force to the uneven plate when screwing from the other side. The method of claim 5, wherein the tightening unit The inner side is screw-coupled, the polarization mode distributed compensation optical fiber grating variable device, characterized in that the separation distance from each other is changed in accordance with the bonding portion. The method of claim 1, wherein the tightening unit A polarization mode distributed compensation fiber grating variable device, characterized in that the fastening means of the gear-shaped protruding member is formed in the longitudinal direction on the outer circumferential surface so as to be rotatable. The method of claim 1 or 7, wherein the rotating unit Polarizer mode distributed compensation optical fiber grating variable device characterized in that the protruding piece is formed on the top of the disc so that the protruding member and the gear bite so as to be able to bite. The method of claim 2, wherein the uneven plate The polarization mode distributed compensation optical fiber grating variable device is inserted into both sides of the crimping portion perpendicular to each other, and has the same lattice period. The method of claim 9, wherein the uneven plate The sum of the lengths of the lattice adjacent to each other among the lattice formed by the two uneven plates is the period of the lattice groove ( Half of) / 2) polarization mode distributed compensation optical fiber grating variable device. The uneven plate of claim 1 or 9, wherein The depth of the grating groove (d1) is formed in the range of 5㎛ to 10㎛, the width of the grating grooves (d2) is a polarization mode distributed compensation fiber grating variable device, characterized in that formed in the range. The uneven plate of claim 1 or 9, wherein Polarization mode distributed compensation fiber grating variable device, characterized in that the grating groove is periodic or aperiodic. delete The uneven plate of claim 1 or 9, wherein The polarization mode distributed compensation fiber grating variable device, characterized in that the grating grooves are the same grouping, or different gratings are formed in combination.