DE3011663A1 - Optical fibre polarisation device - has crystal block with edge face in contact with polished surface of optical conductor - Google Patents

Abstract

The polarisation device has a transparent crystal block (3) with an edge face (2) in contact with a polished section of the optical conductor (1), so that part of the optical wave-field within the latter is coupled with the edge face (2). The absorption of light by the edge face (2) or the block (3) and/or the transfer of light from the optical conductor (1) to the block (3) is dependant on the polarisation. Pref. the block (3) exhibits double refraction with the position of its optical axis chosen so that the refractive indices for two orthogonal polarisation directions are different. These two refractive indices may be respectively below and above the refractive index of the core of the optical conductor (1). The latter is polished to provide a contact surface extending over a given length (L) within the outer sheath or down as far as the core and it may be held in contact with the edge face (2) of the block (3) by the curved edge of a glass plate clamped in turn between two glass blocks.

Description

"Polarizer for Fiber Optic Arrays"

In a variety of fiber optic arrangements, the cut-in is of polarizers required in the light path.

The optical fiber is usually interrupted for this purpose and the interruption is bridged by the fact that the one exiting from one fiber end Light through one or more optical lenses or through more complicated optical arrangements is coupled into the next fiber section. In the beam path can then insert one of the known embodiments of optical polarizers. Such However, arrangements are complex and mechanically sensitive. In contrast, it would be preferable a fiber optic arrangement which causes the light of a certain polarization state is guided in an optical fiber, while the light with orthogonal polarization state is decoupled from the fiber or is absorbed.

The object of the invention is to create such a simple arrangement " which the above disadvantages of known arrangements having.

The invention is described in claim 1. The subclaims contain advantageous developments or embodiments of the invention.

FIG. 1 shows the basic representation of an inventive Arrangement. FIG. 2A shows the cross section through an arrangement according to FIG. 1, where the optical fiber 1 as a single-wave optical fiber with the core 5 and the cladding 4 is formed and with the ground surface with the body 3 in contact is. Single-wave optical fibers are characterized by the fact that they only have the two Lead polarization states of the basic mode (= HE1l mode). You are e.g. B. in the Publication Modenreine Glasfaser-Lichtwellenleiter "by 0. Krumpholz, published in Scientific Reports AEG-TELEFUNKEN 44 (1971), pages 64-70. In FIG. 2A, the optical fiber 1 is not ground down to the core 5. Since with one single-wave fiber, the light guided by the core 5 penetrates deep into the cladding 4, a coupling of the fiber 1 with the body 3 is also achieved when the fiber 1 is not sanded down to core 5. Fig. 2B shows the cross section through a Another embodiment of the invention, wherein the optical fiber 1 as a single-wave Optical fiber is formed with the core 5 and the cladding 4, on one side up is sanded into the core area and with the sanded surface with the Body 3 is in contact. By grinding the optical fiber 1 into the core area a stronger optical coupling between the fiber 1 and the body 3 is achieved. FIG. 2C shows the cross section through a further embodiment of the invention, wherein the optical fiber 1 is a step index profile type multi-wave optical fiber or of the graded index profile type is a core 5 and has a jacket 4, ground on one side down to the core area and is in contact with the body 3.

FIG. 3 shows a plan view of an arrangement according to the invention, consisting of a ground optical fiber 1 and a body 3.

According to the invention, the body 3 and / or its to the optical fiber 1 adjoining surface 2 and / or the optical fiber surface touching the body 3 in such a way that the light of a certain polarization state Pl is guided in the optical fiber, while the light with orthogonal polarization state P2 is coupled out of the fiber or is absorbed.

For the following explanation of arrangements with single-mode optical fibers are shown in FIG. 4 shows the electric and magnetic field lines of the HE11 mode. FIG. 4A shows the field lines of the horizontally polarized, moving in the positive x-direction propagating HE11 mode; FIG. 4B shows the field lines of the vertically polarized, HE11 mode propagating in the positive x-direction. The E-lines of the horizontal polarized HE1l mode run parallel to the xy plane (FIG. 4A), while the Field lines of the vertically polarized HE1l mode run parallel to the xz plane (FIG. 4B).

In an advantageous embodiment of the invention it is therefore proposed that to form the body 3 from a transparent, optically birefringent crystal and to choose the position of the optical axes of the body 3 so that the Refractive index for the light penetrating into the body 3 in two mutually orthogonal polarization states is different. In a further advantageous embodiment it is proposed that that the refractive index for a polarization state P1 in the body 3 is less than is in the core 5 of the optical fiber 1, and that the refractive index for the orthogonal to P1 Polarization state P2 in the body 3 is greater than in the core 5 of the optical fiber t.

This has the consequence that the light in polarization state P2 from the Optical fiber 1 is coupled out into the body 3 and because of the high number of modes of the body from the body 3 is no longer fed back into the optical fiber 1 will. The light in the polarization state P1, however, is in the optical fiber 1 forwarded.

In the case of a uniaxially optically birefringent crystal as Bodies 3 are shown in FIG. 5 and in FIG. 6 the index ellipsoids are drawn into the body 3. In the uniaxial, optically birefringent crystal, the index ellipsoid is rotationally symmetrical. The refractive index for light polarized in the direction of the major axis is ne, for light polarized perpendicular to the main axis nO.

For negatively birefringent crystals, ne <n (FIG. 5), 0 while for positively birefringent crystals ne> no (FIG. 6) applies. The cut surface of the body 3 which is in contact with the optical fiber is shown in FIG. 5 and FIG. 6 the xz plane. In FIG. 5A is the main axis of the crystal in the z-direction, so parallel to the cut surface of the body 3 and normal to the axis of the optical fiber 1. For the horizontally polarized HE11 wave (FIG. 4A), the refractive index nO applies, while for the vertically polarized wave (FIG. 4B) the effective refractive index between ne and n0 lies. If n1 is the refractive index of the fiber core 5 and if nO) n1 is selected, then will the horizontally polarized wave is coupled out of the fiber. Is never ("1 and also the effective refractive index of the vertically polarized wave in the body 3 is less than n1, the vertically polarized wave is guided in the fiber.

In FIG. 5B is the main axis of the crystal 3 in the y-direction, that is normal to the contact surface of fiber and crystal. Again, n0> n1, ne <n1, in addition, let the effective refractive index for the horizontally polarized wave in the crystal be 3 less than n1. In this case, the vertically polarized wave will come out of the fiber coupled out and guided the horizontally polarized wave in the fiber.

Examples of negatively uniaxial birefringent crystals are (for 5890 A wavelength) n n e 0 K N03 1.33 1.51 Na NO3 1.34 1.58 For quartz, n1 = 1,458 In FIG. 6 becomes a positively uniaxially birefringent crystal as body 3 used. Let n <n1 and n> n1 hold.

0 e In addition, in FIG. 6A is the effective refractive index in the crystal for the vertically polarized wave is greater than n1 and in FIG. 6B is the effective refractive index for the horizontally polarized wave greater than n1. In FIG. 6A is then only the horizontally polarized wave guided; in FIG. 6B only becomes the vertically polarized one Shaft guided.

The considerations also apply mutatis mutandis to biaxially birefringent ones Crystals as bodies 3. They are the same Considerations also for circular birefringent crystals are valid as body 3. In the latter case, the arrangement works circularly polarizing.

The arrangement also works in the multimodal case, although here considerations made for the HE1l mode to extend to the higher modes are.

FIG. 7 shows cross sections through a further advantageous embodiment the invention. The optical fiber 1 is common between two glass blocks 7 and 8 embedded with a glass plate 6 (e.g. glued). The glass plate 6 has a curved edge which determines the radius of curvature of the optical fiber 1. The arrangement of optical fibers, glass plates and glass blocks is ground and brought into contact with the body 3.

In a further advantageous embodiment it is proposed that the whole body 3 or its surface 2 instead of birefringent material from a dichroic material. Dichroic materials are off known in the literature and characterized in that their optical absorption is polarization dependent. The arrangements according to FIG. 1 to FIG. 3 and according to FIG. 7 can also be realized with bodies made of dichroic material.

FIG. 8 shows further advantageous embodiments of the invention with dichroic layers 9 and 10 between the fiber 1 and the body 3. Des furthermore, the layer 9 or 10 can be between 1 and 3 in FIG. 8 instead of dichroic Material as a thin metal film (a few 10 to a few 1000 2 thick). One of those Metal film absorbs the vertically polarized Wave much stronger than the horizontally polarized wave.

This metal film 9 or 10 can be on its own carrier or else applied directly to the sanded surface of the fiber 1 or to the body 3 (e.g. by vapor deposition or sputtering).

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Claims (11)

Claims I PolariJator for fiber optic arrangements, thereby indicates that an optical fiber (1) is ground over a length L and is in contact over the length L with the delimiting surface (2) of a body (3), so that part of the optical wave field from the optical fiber (1) covers the surface (2) penetrates and penetrates the body (3), and that the absorption of light in the surface (2) or the body (3) and / or the coupling of the light the optical fiber (1) in the body (3) is polarization dependent. 2. Polarizer according to claim 1, characterized in that the optical fiber (1) is a single-wave and is ground in the jacket (4). 3. Polarizer according to claim 1, characterized in that the optical fiber (i) is a single-wave and is sanded down to the core (5). 4. Polarizer according to claim 1, characterized in that the optical fiber (1) a multi-wave from Step index profile type or of the graded index profile type and is sanded down to the core (5). 5. Polarizer according to claim 1, characterized in that the body (3) is designed in such a way that the light of a polarization state Pl is guided in the optical fiber (1), while the light is orthogonal to it Polarization state P2 is coupled out or absorbed from the optical fiber. 6. Polarizer according to claim 5, characterized in that the body (3) is a transparent, optically birefringent crystal, and that the position of the optical axes of the body (3) is chosen so that the refractive indices for the Polarization states P1 and P2 of the light penetrating the body (3) are different are. 7. Polarizer according to claim 6, characterized in that the refractive index for the polarization state P1 in the body (3) is smaller than that in the core (5) the optical fiber (1), and that the refractive index for the orthogonal polarization state P2 in the body (3) is greater than that in the core (5) of the optical fiber (1). 8. Polarizer according to claim 1, characterized in that the optical fiber (1) lies on the curved edge of a glass plate (6), together with the glass plate (6) is embedded between two glass blocks (7 and 8) that the arrangement consists of optical fiber (1), glass plate (6) and glass blocks (7 and 8) on the side is ground flat with the optical fiber (1), the optical fiber (1) over a length L is ground, and that the flat ground side with the surface (2) of the body (3) is brought into contact. 9. Polarizer according to claim 5, characterized in that the body (3) or the surface (2) consists of a dichroic material. 10. Polarizer according to claim 1, characterized in that on the Surface (2) of the body (3) a thin metal film (9 or 10) is applied. 11. Polarizer according to claim 1, characterized in that a thin Metal film (9 or 10) applied to the ground surface of the optical fiber (1) is.