JPH0615012U - Optical coupling device - Google Patents

Abstract

(57) [Abstract] [Purpose] Easily match the polarization axis of a polarization-maintaining optical fiber with the polarization axis of linearly polarized light incident on this optical fiber. [Configuration] A polarization-maintaining optical fiber 17 that preserves the polarization plane and propagates light, and an output light that is provided coaxially with the polarization-maintaining optical fiber 17 so as to face the light input / output port and is collimated light, An aspherical lens 12 that collects the collimated light and makes it enter the polarization-maintaining optical fiber 17, and is provided rotatably on the same axis as the aspherical lens 12 so as to face the lens 12, and to set the polarization axis of linearly polarized light. Λ / 2 for rotating
It is composed of a λ / 2 plate holder 25 that supports the plate 29.
The polarization-maintaining optical fiber 17 is detachably attached to the aspherical lens 12 side.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to an optical coupling device that efficiently propagates incoming and outgoing light of a polarization-maintaining optical fiber.

[0002]

[Prior art]

 Conventionally, when an optical fiber is used, a ferrule for introducing the light into the optical fiber and a connector for holding and fixing the ferrule part are provided on both end faces for entering and emitting the light. When collimating or converging light emitted from an optical fiber using these optical fiber connectors, install a collimating lens or a converging lens near the end of the optical fiber ferrule to prevent diffused light emitted from the optical fiber. It was used after being converted into parallel light or convergent light.

It is known to integrate a lens and a receptacle used for easily making parallel or convergent light emitted from an optical fiber, and for connecting and fixing the optical fiber. When attempting to enter parallel or converged light into another optical fiber using such a lens built-in receptacle, the target optical fiber was a single mode optical fiber, a multimode optical fiber, etc. In this case, for example, when it is not necessary to specify the polarization of the incoming and outgoing light, prepare another lens-equipped receptacle and these optical fibers in the same manner, and install and position them facing each other on the same optical axis. It was good to introduce light into the optical fiber.

However, when a polarization-maintaining optical fiber is targeted, not only is it possible to efficiently enter and exit light, but also the polarization axis of the incident light that enters the optical fiber and the light receiving side that receives this incident light are In the case of a polarization-maintaining optical fiber, it is necessary to adjust the polarization axis of the incident light and the polarization axis of the receiving-side polarization-maintaining optical fiber to bring them into a very close state.

Such adjustment is performed, for example, as shown in FIG. A prism 5 having an LD light source 1, a polarization-preserving optical fiber 2 and a collimator 3 for improving the polarization accuracy of linearly polarized light emitted from the collimator 3, and a λ / 4 plate for converting this linearly polarized light into circularly polarized light. 6. A prism 7 is provided which allows the direction of linearly polarized light to be adjusted as desired by adjusting the direction of the polarization axis and rotating it. Make adjustments.

Similarly, referring to FIG. 6, an LD light source 1, a polarization-maintaining optical fiber 2, a collimator 3, a prism 8 and a λ / 2 plate 9 are provided. It is possible to obtain the polarization direction. There is also an optical system configuration in which the prism 5 is not installed and only the λ / 2 plate 9 is used.

All of these are premised on that the polarization axis direction of the incident light entering the polarization-maintaining optical fiber 2 and the polarization axis of the polarization-maintaining optical fiber 2 are aligned.

[0008]

[Problems to be solved by the device]

 However, in the case of the conventional optical coupling device described above, the prism 5, the λ / 4 plate 6 and the prism 7 are provided as separate members in FIG. 5, and the prism 8 and the λ / 2 plate 9 are provided as separate members in FIG. However, there is a problem in that it becomes large and complicated and adjustment time is required.

The present invention has been made in view of the above problems, and an object of the present invention is to provide an optical coupling device that is small in size, is not bulky, and can easily adjust the polarization axis.

[0010]

[Means for Solving the Problems]

 In order to solve the above-mentioned problems, an optical coupling device according to the present invention comprises an optical fiber connector for detachably connecting a polarization-maintaining optical fiber that preserves the polarization plane and propagates light, and the polarization-maintaining optical fiber. A lens holder that is provided coaxially with the fiber and faces the light input / output port, and that has a lens that adjusts the output light or collects the incident light and makes it enter the polarization-maintaining optical fiber, and coaxially with the lens. And a polarization axis adjusting device that is rotatably provided facing the lens and that rotates a polarization axis of an arbitrary polarization plane of the incoming and outgoing light.

[0011]

[Action]

 With the above configuration, by rotating the polarization axis adjusting device, the polarization axis of the incident light to the polarization-maintaining optical fiber or the output light from this polarization-maintaining optical fiber is rotated and the polarization of the linearly polarized light is incident. Match the polarization axis of the wavefront preserving optical fiber.

[0012]

【Example】

 An embodiment of the present invention will be described below with reference to the accompanying drawings. FIG. 1 is a sectional view showing a polarization-maintaining optical fiber receptacle as an optical coupling device according to this embodiment, and FIG. 2 is a partial sectional view showing a state in which the polarization-maintaining optical fiber receptacle is connected to an optical fiber. .

The polarization-maintaining optical fiber receptacle of this embodiment is roughly constituted by a lens holder 11, an optical fiber connecting portion 15, and a λ / 2 plate holder 25 as a polarization axis adjusting device. The lens holder 11 is formed in a bottomed cylindrical shape, and an aspherical lens 12 for collimating light emitted from an optical fiber 17 described later and collecting the collimated light on an optical fiber 17 is attached to the bottom portion 11A. There is. An inflow hole (not shown) for allowing the adhesive to flow into the side surface of the aspherical lens 12 is provided near the bottom 11A of one end (the right end in the figure) of the inner peripheral wall of the lens holder 11. The aspherical lens 12 is fixed to the bottom portion 11A by the adhesive that has flowed in from the inflow hole. The bottom portion 11A is provided with a press-fitting protrusion 11B for press-fitting into a lens holder receiving portion 19C of a later-described middle cylinder portion 19, and the aspherical lens 12 and the optical fiber 17 are provided at the center of the press-fitting protrusion 11B. A communication hole 11C for allowing light to pass through is provided between the element wire (not shown). On the outer circumference of the other end of the lens holder 11, there is provided a locking groove 11D which is formed in an annular shape over the entire circumference thereof and into which a fixing stopper 28 described later is fitted. The locking groove 11D has a depth of 0.5 mm and a V-shaped cut with a cross section of 30 °.

The optical fiber connection portion 15 is mainly provided with a middle tubular portion 19 into which the ferrule tip portion 18 of the optical fiber 17 is inserted, and is provided outside the middle tubular portion 19, and the connection plug 20 of the optical fiber 17 is screwed. It is composed of an outer cylinder part 21 to be worn. The middle tubular portion 19 has a small-diameter ferrule receiving portion 19A into which the front end 18 of the ferrule is directly inserted, a medium-diameter press-fitting portion 19B that is press-fitted into the middle tubular receiving portion 21B of the outer tubular portion 21, and the lens holder 11. The lens holder receiving portion 19C into which the press-fitting protrusion 11B is press-fitted.

The outer cylinder portion 21 is composed of a screw cylinder portion 21A to which the connection plug 20 of the optical fiber 17 is directly screwed, and a middle cylinder receiving portion 21B into which the press-fitting portion 19B of the middle cylinder portion 19 is press-fitted. There is.

The λ / 2 plate holder 25 is arranged on the other end side of the lens holder 11 with its opening closed. The λ / 2 plate holder 25 is entirely formed in a cylindrical shape with a bottom, and is composed of a cylinder portion 26 and a λ / 2 plate support plate portion 27. At one end (right end in the figure) of the tubular portion 26, there is provided a flange portion 26A formed by expanding the diameter for rotating the holder 25. A plurality of holder fixing stoppers 28 for fixing the λ / 2 plate holder 25 to the lens holder 11 by being locked in the locking groove 11D are provided on the peripheral wall of the cylindrical portion 26. The λ / 2 plate support plate portion 27 is formed in a disk shape, is provided with a through hole 27A for the collimated light, and is attached with the λ / 2 plate 29. The λ / 2 plate 29 has a diameter of 6 mm and a thickness of 0.9 mm. A circular step portion 31 having a diameter of 6 mm and a thickness of 1 mm is provided on the inner side surface of the λ / 2 plate support plate portion 27, and the λ / 2 plate 29 is bonded and fixed to the circular step portion 31. Further, the λ / 2 plate support plate portion 27 is set to have a diameter of 9 mm and a thickness of 3 mm. The tubular portion 26 and the λ / 2 plate support plate portion 27 are also integrally fixed.

When connecting the optical fiber 17, the ferrule tip 18 of the connection plug 20 provided at the end of the polarization-maintaining optical fiber 17 is inserted into the ferrule receiving portion 19 A of the optical fiber connecting portion 15. Then, the connection plug 20 is screwed onto the threaded cylindrical portion 21A, and the optical fiber element wire embedded in the ferrule tip portion 18 is positioned so as to face the aspherical lens 12.

When two polarization-maintaining optical fibers 17 are connected for the purpose of providing an optical device in the middle of fiber transmission, the polarization-maintaining optical fiber 17 is connected to the end of one polarization-maintaining optical fiber 17 at the end. Lens and a receptacle with a λ / 2 plate are connected, and a receptacle with a lens is connected to the other optical fiber 17, and the two receptacles are arranged so as to face each other.

When the polarization axis of the collimated light emitted from one polarization-maintaining optical fiber 17 is aligned with the polarization axis of the other polarization-maintaining optical fiber 17, the holder for fixing the polarization-maintaining optical fiber receptacle is used. Loosen the stopper 28 and turn the λ / 2 plate holder 25. As a result, the λ / 2 plate 29 rotates, and the polarization axis of the output collimated light is rotated to match the polarization axis of the other polarization-maintaining optical fiber 17.

Here, a method of evaluating the coupling loss will be described with reference to FIG. Reference numeral 35 in the figure denotes an LD light source, and one end of a first polarization-maintaining optical fiber 36 is connected to the LD light source 35. A lens-equipped receptacle (hereinafter referred to as “receptacle”) 37 is connected to the other end of the first polarization-maintaining single-mode fiber 36. A polarization-maintaining optical fiber receptacle (hereinafter referred to as "receptacle 37") which is coaxially opposed to the receptacle 37 at a position 60 mm away and incorporates the aspherical lens 12 and the λ / 2 plate 29 having the above-described configuration according to the present embodiment. A “receptacle”) 38 is connected to one end of a second polarization-maintaining single-mode fiber 39. A detector 41 is installed at an emission end 40 from which light is emitted from the second polarization-maintaining single-mode fiber 39, and the optical power meter 43 detects the light intensity. The light intensity is detected by detecting the light intensity (I ₀ ) at the time of exiting the receptacle 37 and the light intensity (I ₁ ) exiting from the receptacle 38 in FIG. 3, and calculating the ratio of the light intensities (I ₀ ) and (I ₁ ). The coupling loss was calculated from, and 1.8 dB was obtained in the above example.

Next, a crosstalk evaluation method will be described with reference to FIG.

The LD light source 35, the first polarization-maintaining single-mode fiber 36, the receptacle 37, the polarization-preserving optical fiber receptacle 38, and the second polarization-maintaining single-mode fiber 39 have the same configuration as in the coupling loss evaluation method. It has become. A receptacle 45 having no λ / 2 plate 29 is connected to the other end of the second polarization-maintaining single-mode fiber 39. A prism 46 is arranged on the exit side of the receptacle 45. The prism 46 transmits all the emitted light when its polarization axis is parallel to the polarization axis of the emitted light, and blocks the emitted light when they are orthogonal. The detector 44 including the detector 41 and the optical power meter 43 is the same as in the case of the coupling loss evaluation method. The detector 44 detects the light emitted from the receptacle 45 through the prism 46.

When adjusting the polarization axis of the light emitted from the receptacle 37 and the polarization axis of the second polarization-maintaining single-mode fiber 39, the λ / 2 plate 29 is rotated to rotate the polarization axis of the emitted light. . The polarization of the incident light can be adjusted by rotating the λ / 2 plate 29 of the receptacle 38 attached to the polarization-maintaining optical fiber on the receiving side, and the polarization axis and the polarization of the second polarization-maintaining optical fiber 39 are adjusted. It changes from the state in which the axis is largely deviated to the point in which the degree of misalignment is reduced and they coincide with each other. The amount of this change is detected.

The prism 46 is rotated together with the rotation of the λ / 2 plate 29, and the light emitted from the receptacle 45 is detected by the detector 44 via the prism 46. The optical power meter 43 reads the maximum and minimum values detected by the rotation of the prism 46. The maximum value and the minimum value change depending on the degree of deviation between the polarization axis of the emitted light and the polarization axis of the second polarization-maintaining single-mode fiber 39. The position where the ratio between the maximum value and the minimum value is the maximum is the position where the polarization axis of the emitted light and the polarization axis of the second polarization-maintaining single-mode fiber 39 match, and is called crosstalk.

While rotating the λ / 2 plate 29, a position where the crosstalk is maximized is searched for, and the holder fixing stopper 28 is tightened at the position where the crosstalk is maximized to fix the λ / 2 plate holder 25. In this example, 33 dB of crosstalk was obtained.

As described above, the polarization axis can be adjusted simply by rotating the λ / 2 plate holder 25, and the two polarization-maintaining optical fibers 17 can be easily optically coupled.

Further, since the λ / 2 plate holder 25 is mounted on the lens holder 11, the structure is simple and the size can be reduced.

Further, since the polarization-preserving optical fiber receptacle 38 and the polarization-preserving optical fiber 17 are connected by the connection plug 20 provided in the polarization-maintaining optical fiber 17, these connections can be facilitated. This facilitates connection with an arbitrary polarization-maintaining optical fiber 17.

In the above embodiment, the λ / 2 plate 29 is used as the polarization axis adjusting device, but other means may be used. For example, the polarization axis may be adjusted by disposing two λ / 4 plates facing each other and rotating either one of them. Further, if it is possible to sacrifice some loss, one of the pair of λ / 4 plates may be replaced with a prism and the function of the λ / 4 plate may be substituted by this prism.

Further, in the above-described embodiment, as an example in which the beam cross-sectional shape of the outgoing light or the incoming light is shaped into a predetermined cross-sectional shape by the aspherical lens 12, the outgoing light is collimated and the collimated light is directed to the optical fiber 17. Although the case of collecting light has been described, the present invention is not limited to this, and may be formed into the following cross-sectional shape. That is, in addition to the collimated light for the emitted light, the incident light may be focused on the optical fiber 17 and the incident and emitted light may be expanded in the form of parallel light or conversely reduced in diameter.

Further, in the above-described embodiment, the receptacle is provided with the optical fiber connecting portion 15 having the threaded tube portion 21A as a means for connecting the polarization maintaining optical fiber 17, and the polarization maintaining optical fiber 17 is provided with the connection plug 20. Although they are provided and screwed to each other, they may be connected by other means such as a press-fitting configuration or a configuration in which the ferrule part is integrally molded with the receptacle.

[0032]

[Effect of device]

 As described above in detail, according to the present invention, since the λ / 2 plate for rotating the polarization axis of the linearly polarized light is provided, it is possible to rotate the polarization axis of the incident light or the outgoing light to the polarization-maintaining optical fiber. , It is possible to easily match the linearly polarized light with the polarization axis of the optical fiber to which it is incident.

Since the lens and the λ / 2 plate side and the optical fiber can be attached and detached, the optical fiber can be easily connected to any polarization-maintaining optical fiber. This allows easy optical coupling of any two polarization-maintaining optical fibers.

[Brief description of drawings]

FIG. 1 is a cross-sectional view showing a polarization-maintaining optical fiber receptacle according to the present invention.

FIG. 2 is a partially cutaway side view showing a state in which a receptacle for a polarization-maintaining optical fiber and a polarization-maintaining optical fiber are connected.

FIG. 3 is a schematic configuration diagram of an apparatus used when measuring a coupling loss.

FIG. 4 is a schematic configuration diagram of an apparatus used when measuring crosstalk.

FIG. 5 is a schematic configuration diagram showing a first conventional example.

FIG. 6 is a schematic configuration diagram showing a second conventional example.

[Explanation of symbols]

11 ... Lens holder, 11D ... Locking groove, 12 ... Aspherical lens, 15 ... Optical fiber connection part, 17 ... Polarization preserving optical fiber, 18 ... Ferrule tip part, 25 ... λ / 2 plate holder, 29 ... λ / 2 plates.

Claims (1)

[Scope of utility model registration request] 1. An optical fiber connecting part for detachably connecting a polarization-maintaining optical fiber that preserves the polarization plane and propagates light, and a polarization-maintaining optical fiber coaxially facing the light input / output port. A lens holder provided with a lens for shaping the beam cross-section of the outgoing light or the incident light into a predetermined cross-sectional shape; and a lens holder that is rotatably provided coaxially with the lens facing the lens and facing the incoming and outgoing light. An optical coupling device comprising a polarization axis adjusting device for rotating a polarization axis of a polarization plane.