EP2220526A1 - Coupling device for coupling optical fibers - Google Patents

Abstract

The invention relates to a coupling device for the coupling of optical fibers, having a first side (S1) for the coupling of first optical fibers (L1) to the coupling device (1, 2, 3, 4), and a second side (S2) for the coupling of second optical fibers (L2) to the coupling device (1, 2, 3, 4), and an optical system (10, 20, 30, 40) that is arranged between the first and second sides (S1, S2) of the coupling device. The optical system (10, 20, 30, 40) modifies a beam path of light that is coupled out of the first optical fibers (L1) and coupled into the coupling device on the first side (S1) in such a manner that the light is coupled out of the coupling device on the second side (S2) and into the second optical fibers (L2), wherein the first optical fibers (L1) are spatially arranged with respect to each other differently from the second optical fibers (L2).

Description

description

Coupling device for coupling optical waveguides

The invention relates to a coupling device for coupling optical waveguides, for example a coupling device, with which optical waveguides which are arranged on an optical chip are coupled to optical waveguides of a fiber ribbon.

In a fiber ribbon a plurality of optical fibers are arranged side by side. In one possible embodiment of the fiber ribbon, in which the optical waveguides have a diameter of 125 μm, the spacing (pitch) of the individual optical waveguides of the fiber ribbon can be, for example, 250 μm. The optical fibers of the fiber ribbon are generally connected to a device for processing optical signals transmitted via the optical fibers or to a conversion device for converting optical signals into electrical signals.

Such devices for optical signal processing can be arranged on a chip.

For supplying light to the signal processing devices, a plurality of optical waveguides are mounted on the chip. For coupling the optical fibers of the fiber ribbon with the optical waveguides embedded on the chip, a coupling device is used, wherein the optical fibers are arranged on the chip in the same spatial arrangement, in particular at the same distance from each other, as the optical fibers of the fiber ribbon. The optical waveguides on the chip are therefore due to the distance of the optical waveguide of the fiber ribbon, for example, even if arranged at a distance of 250 microns on a substrate of the chip. Due to the large distance between the optical waveguides on the chip, valuable chip area is generally lost.

It is desirable to specify a coupling device with which it is possible to couple optical waveguides, which are each arranged spatially differently, for example, to different distances from one another, to each other. Furthermore, there is a need to provide a system for coupling fiber optic cables. It is also desirable to provide a method for coupling optical fibers.

In claim 1, such a coupling device for coupling optical waveguides, in particular of optical waveguides of a fiber ribbon, to optical waveguides, which are arranged on a substrate of a chip specified. The coupling device makes it possible, in particular, to couple the optical waveguides of the fiber ribbon to optical waveguides which are arranged on the substrate of the chip at a smaller distance than the optical waveguides of the fiber ribbon.

An embodiment of the coupling device for coupling optical waveguides comprises a first side for coupling first optical waveguides to the coupling device and a second side for coupling second optical waveguides to the coupling device. The first optical waveguides are arranged on the first side of the coupling device relative to one another spatially differently than the second optical waveguide on the second side of the coupling device. The coupling device further comprises an optical system which is connected between the first and second sides of the coupling is arranged device. The optical system alters a beam path of light coupled out of the first optical waveguide and coupled into the coupling device on the first side such that the light on the second side is coupled out of the coupling device and coupled into the second optical waveguide. The changing of the beam path is effected by a refraction of light on the optical system, wherein the refraction of light is dependent on an impingement of the radiation on the optical system.

The optical system may include a lens. The lens may be formed, for example, as a converging lens. The coupling device can furthermore comprise further lenses, which are arranged between the lens and the second optical waveguides. Each of the further lenses is in each case assigned to one of the second optical waveguides in order to couple the light emitted by the lens into the one of the second optical waveguides assigned to the respective one of the second lenses. The further lenses can be arranged in the coupling device between the lens and one of the first and second sides of the coupling device. The optical system may also include a spherical lens.

The optical system may, for example, comprise optical elements each containing optical waveguides. The respective optical fibers of the optical elements are coupled to the first or second optical fibers. The optical elements are each formed on a side facing the spherical lens as a spherical half-shell.

The optical system can output the beam path of the first optical waveguides arranged in a plane. - A -

th light change such that the light is emitted at the second side of the coupling device and coupled into the arranged in different planes second optical waveguide.

The optical system may for example contain a plurality of plane-parallel plates. The plurality of plane-parallel plates may each be assigned to one of the first and second optical waveguides in order to change the beam path of the light coupled out of one of the first optical waveguides and coupled into the coupling device on the first side in such a way that the light on the second side emitted from the coupling device and coupled into one of the second optical waveguide. The plurality of plane-parallel plates may be arranged in an alternating direction with respect to each other.

The optical system may further include a plurality of prisms. In each case one of the prisms can be assigned to one of the first optical waveguides on the first side of the coupling device. Another of the prisms may be assigned to one of the second optical waveguides on the second side of the coupling device. The one of the prisms can be oriented in such a way that the light emerging from the one of the first light waveguides is irradiated on the first side of the coupling device into the one of the prisms and is directed onto the further one of the prisms. The further of the first prisms can be oriented such that the light directed onto the further one of the prisms is emitted on the second side of the coupling device and coupled into one of the second optical waveguides. For example, the coupling device may include a guide pin that protrudes from the coupling device on one of the first and second sides for attaching the coupling device to a component that contains the first and second optical waveguides. The coupling device may further include a cavity adapted to receive a guide pin of a device including the first and second optical fibers to secure the coupling device to the device. The other lenses may be attached to the guide pin.

The first optical waveguides can be arranged on a first component. The second optical waveguides can be arranged on a second component. The first optical waveguides can be arranged on the first component at a different distance from one another than the second optical waveguides are arranged on the second component.

The first optical waveguides can be arranged on a first component and the second optical waveguides can be arranged on a second component. The first optical waveguides are arranged on the first component in a plane. The second optical waveguides are arranged on the second component in different planes.

At least one of the first and second components may be formed, for example, as an optical chip. At least one of the first and second components can also be designed as a ferrule, for example.

A system for coupling optical waveguides comprises a first component comprising first optical waveguides and a second component comprising second optical waveguide. The system further comprises a coupling device having a first side, at which the first component is coupled to the coupling device, and a second side, at which the second component is coupled to the coupling device. The first optical waveguides are spatially differently arranged in the first component on the first side of the coupling device relative to one another than the second optical waveguides are arranged in the second component on the second side of the coupling device. The coupling device further comprises an optical system. The optical system alters a beam path of light coupled out of the first optical waveguides and coupled into the coupling device on the first side such that the light is decoupled from the coupling device at the second side and coupled into the second optical waveguide. The changing of the beam path is effected by a refraction of light on the optical system, wherein the refraction of light is dependent on the impingement of the beam path on the optical system.

The optical system may include a lens, such as a condenser lens. The system may also include other lenses disposed between the lens and the second optical fibers. Each of the further lenses is in each case assigned to one of the second optical waveguides in order to couple the light emitted by the lens into the one of the second optical waveguides assigned to the respective one of the second lenses. Furthermore, the optical system may include a plurality of plane-parallel plates. The plurality of plane-parallel plates may be arranged to each other in an alternating direction. A method for coupling optical waveguides provides for using a coupling device, wherein first optical waveguides are spatially arranged differently on a first side of the coupling device relative to each other, as second optical waveguides are spatially arranged on a second side of the coupling device. The method further provides the coupling out of light from the first optical waveguides. The decoupled light is coupled into the coupling device. A beam path of the light coupled into the coupling device is changed by means of an optical system such that the light coupled out of the coupling device is coupled into second optical waveguide. In this case, the beam path of the light is changed by a refraction of light at the optical system, wherein the refraction of light is changed depending on the impact of the beam path on the optical system.

In the method, the first optical waveguides on the first side of the coupling device can be arranged at a different distance from one another than the second optical waveguides on the second side of the coupling device.

The first optical waveguides can be arranged on the first side of the coupling device in a plane. The second optical fibers can on the second side of the

Coupling device can be arranged in different levels.

The invention will be explained in more detail below with reference to figures which show exemplary embodiments of the present invention. Show it: FIG. 1 shows an embodiment of a coupling device for coupling optical waveguides, which have different distances from each other,

FIG. 2 shows a further embodiment of a coupling device for coupling optical waveguides, which each have different distances from each other,

FIG. 3 shows a further embodiment of a coupling device for coupling optical waveguides which have different distances from each other,

FIG. 4 shows a further embodiment of a coupling device for coupling optical waveguides which have different distances from each other,

5 shows an arrangement of optical waveguides of a fiber ribbon and of optical waveguides of a chip, which are arranged in different spatial planes relative to one another,

FIG. 6 shows an embodiment of a coupling device for coupling optical waveguides, which are arranged spatially in different planes,

Figure 7 shows an embodiment of an optical system for

Coupling optical waveguides spatially arranged in different planes

FIG. 8 shows a further embodiment of an optical system for coupling optical waveguides, which are arranged spatially in different planes. FIG. 1 shows an embodiment of a coupling device 1 for coupling optical waveguide L1 to optical waveguide L2. The optical waveguides L1 are arranged, for example, on a component 100 at a spacing (pitch) P1 relative to one another. The device 100 may be an optical chip, wherein the optical waveguide Ll are embedded in a substrate 101 of the optical chip. For example, devices for signal processing of the light transmitted via the optical waveguide L1 are arranged on the optical chip 100. By way of example, optical transmitting or receiving devices or also optoelectric conversion devices for converting optical signals into electrical signals and for converting electrical signals into optical signals can be arranged on the optical chip 100.

On a component 200, optical waveguides L2 are arranged at a pitch P2 relative to one another. The optical waveguides L2 are arranged, for example, as fiber ribbons. The component 200 may be a ferrule, wherein the optical waveguide L2 are inserted in grooves of the ferrule. The ferrule may be, for example, an MT ferrule. The distance P2, with which the optical waveguides L2 are arranged in the ferrule 200 spatially to each other, is greater than the distance Pl, which have attached to the optical chip 100 optical waveguide Ll to each other.

In order to couple the optical waveguide L1 to the optical waveguides L2, a coupling device 1 is arranged between the components 100 and 200. The coupling device 1 has an optical system 10, with which it is possible to couple light which is coupled out of one of the optical waveguide Ll in an optical waveguide L2 associated with the optical waveguide L1. An optical path of the light, which is coupled into the coupling device 1 by one of the optical waveguides L1, is focused onto one of the optical waveguides L2 by a refraction of light on the optical system. In the coupling device, the light can be transmitted between the optical waveguides L1 and the optical system 10 and between the optical system 10 and the optical waveguides L2 by a free space propagation, wherein the transmission medium is, for example, air. The refraction of light takes place as a function of the impact of the beam path on the optical system.

The refraction of light depends, for example, on the direction or angle at which the light impinges on the optical system 10. The optical system may, for example, have a curved surface. The curvature of the surface of the optical system 10 is selected such that the optical path of the light, which is radiated by the optical waveguides Ll in the coupling device is changed so that the light emerging from the optical system is coupled into the optical waveguide L2. In addition to the curvature of the surface of the optical system, the thickness of the optical system and the distance of the optical system 10 between the optical waveguides L1 on an input side of the coupling device and the optical waveguides L2 on the output side of the coupling device can be selected such that the Optical fibers Ll coupled light is coupled into the optical waveguide L2. In this case, the light waveguide Ll and the light waveguide L2 can be arranged spatially different from each other. The optical waveguides L1 and L2 can in particular be arranged at a different distance from each other. The optical system 10 may include a lens 11, such as a condenser lens. The lens 11 is arranged in the coupling device 1 such that light which is coupled out of one of the optical waveguides L1 and irradiated on one side S1 of the coupling device 1 into the coupling device is radiated by the lens 11 on a side S2 of the coupling device out of the coupling device and is coupled into the light waveguide L2 associated with the optical waveguide L1. Depending on the magnification factor of the lens 11, optical fibers arranged on different sides of the lens 11 at different distances can be coupled to each other. For example, with the arrangement shown in FIG. 1, optical waveguides L1, which are arranged on the side S1 of the coupling device on the optical chip 100 at a distance of 30 .mu.m, can be coupled to optical waveguides L2, which on the side S2 of the coupling device take the form of a Fiber ribbons are arranged at a distance of 250 microns to each other.

For the mechanical coupling of the coupling device 1 to the component 100 or to the component 200, the coupling device 1 contains guide pins 50 which protrude from the coupling device on the side S1 or S2. The guide pins 50 are inserted into cavities 60 of the components 100, 200. When the optical waveguides L1 on the chip 100 and the optical waveguides L2 in the ferrule 200 with respect to the cavities 60 are aligned, light coupled out of one of the optical waveguides L1 is coupled into the optical waveguide L2 associated with the optical waveguide L1. In the embodiment shown in Figure 1, the input and output sides of the coupling device are interchangeable. For example, light which is coupled out of one of the optical waveguides L2 can be irradiated on the side S2 into the coupling device 1 and radiated by the optical system 10 on the side S1 and coupled into the optical waveguide L1 associated with the optical waveguide L2.

The length and width of the coupling device 1 is dependent on the number of optical waveguides to be coupled, the distance between the optical waveguides to each other and the numerical aperture of the optical waveguide. In a system with a pitch of the optical fibers of 50 microns on an input side of the coupling device and a distance of further optical fibers on an output side of the coupling device of 127 microns, about 100 optical fibers can be coupled by a coupling device with a length of 30 mm to each other when the Optical waveguide on the input and output side each have a numerical aperture of 0.15.

FIG. 2 shows a further embodiment of a coupling device 1, in which the optical system 10 has additional lenses 12 in addition to the lens 11. The lenses 12 are each assigned to one of the optical waveguides L2. With the embodiment shown in Figure 2 losses in the coupling of the optical waveguide Ll with the optical waveguides L2 are largely avoided. The light incident on one of the lenses 12 from the lens 11 is re-focused by the lens 12 and projected onto the optical fiber L2 associated with the respective lens 12. In the embodiment shown in FIG. 2, the further lenses 12 are integrated in a housing 70 of the coupling device 1. In the embodiment shown in FIG. 3, the further lenses 12 are arranged outside the housing 70. The lenses may, for example, be designed as a component, with the lenses being connected to one another. The arrangement of the lenses 12 may have eyelets 13 at their ends. For attachment of the lenses 12 on one of the sides Sl and S2 of the coupling device, the eyes 13 are pushed onto the guide pins 50.

The optical waveguides L1 and L2 generally have different emission / acceptance angles, which depend on the respective index profile of the optical waveguides L1 and L2. In the embodiments of the coupling device 1 shown in FIGS. 2 and 3, power losses attributable to the different emission / acceptance angles of the optical waveguides L1 and L2 are avoided by arranging lenses 12 on at least one of the sides S1 or S2. Lenses 12, which are connected upstream of the optical waveguides, can be used in particular if the ratios of the emission angles of the optical waveguides L1 and L2 do not correspond to the ratio of the distance differences between the optical waveguides L1 and L2. Furthermore, power losses are avoided by the lenses 12, for example, when the lens 11 is enlarged in a different ratio than the ratio of the angles of emission of the optical waveguides L1 and L2 relative to one another.

In addition to the two embodiments shown in FIGS. 2 and 3, in which the further lenses 12 are designed as discrete components, it is possible for the lenses 12 to be inserted into the ends of the optical waveguides L1 and L2. tegrieren. The lenses 12 can be integrated into the optical waveguides, for example, by rounding the fiber ends of the optical waveguides L1 or L2.

FIG. 4 shows a further embodiment of a coupling device 2. On the component 100, optical waveguides L1 are arranged at a smaller distance from one another than optical waveguides L2 in which the device 200 is arranged. The component 100 may be, for example, an optical chip, wherein the optical waveguide Ll with optical assemblies, for example, with on-chip transmitting or receiving devices are connected. The component 200 may be a ferrule, for example an MT ferrule, in which the optical waveguides L2 having a diameter of 125 μm, for example, are arranged at a distance P2 of 250 μm from each other. Between the components 100 and 200, the coupling device 2 is provided for coupling the optical waveguide Ll with the optical waveguides L2. The coupling device 2 is mechanically coupled to the components 100 and 200 via guide pins 50, which engage in cavities 60 of the components 100 and 200, respectively.

The coupling device 2 comprises an optical system 20 comprising a spherical lens 21 and optical elements 22a and 22b. The optical elements 22a and 22b are each formed on a spherical lens 21 facing side S22a, S22b as Halbkugelschalen. The magnification factor of the lens arrangement of the optical system 20 is formed by the ratio of the different radii of the hemispherical shells 22a and 22b. The optical elements 22a and 22b respectively have optical fibers 23a and 23b coupled to the optical fibers L1 and L2. The optical waveguides 23a and 23b are each in the region of the hemispherical Side S22a and S22b of the optical elements 22a and 22b aligned with the center of the spherical lens 21. Since each light beam passes through the center of the lens 21, in this embodiment, the diameter of the lens 21 is independent of the number of optical fibers to be coupled.

FIG. 5 shows a different spatial arrangement of optical waveguides L1 and L2. The optical waveguides L1 are arranged, for example, on a substrate of an optical chip in a plane El. The optical waveguides L2 can be, for example, optical waveguides of a fiber ribbon, which are arranged in a ferrule, for example, in two layers in planes E2 and E3. The ferrule may, for example, be an MT ferrule formed with correspondingly two-layered grooves.

FIG. 6 shows an embodiment of a coupling device 3 with which it is possible to couple light which is decoupled from the optical waveguides L1 into the optical waveguides L2 which are arranged in different planes as shown in FIG. The coupling device 3 is arranged between a component 100 and a component 200. The component 100 may be formed, for example, as an optical chip, are arranged on the optical fiber Ll in a plane El adjacent to each other. In the device 200, the optical fibers L2 are arranged in different planes E2 and E3. The coupling device 3 is fastened to the components 100, 200 by guide pins 50 which are inserted into cavities 60 of the components 100, 200. The coupling device 3 contains an optical system 30 which contains plane-parallel plates 31a, 31b corresponding to the number of optical waveguides L1, L2 to be coupled. Each pair of optical fibers Ll, L2 is assigned to one of the plane-parallel plates. The plane-parallel plates 31 a, 31 b are arranged alternately with respect to their alignment in a row along the sides Sl and S2 of the coupling device 3. The alternating arrangement of the plane-parallel plates makes it possible to couple light, which is coupled out of the optical waveguides L1, into the optical waveguide L2 arranged in different planes E2 and E3.

Figure 7 shows the arrangement of a plane-parallel plate 31a, which is associated with an optical fiber pair Ll, L2. The light beam coupled out of the optical waveguide L1 is irradiated into the coupling device on one side Sl of the coupling device 3. The light beam strikes one side of the plane-parallel plate 31a and is deflected downwardly within the plane-parallel plate. After emerging from the plane-parallel plate, the light beam at the

Side S2 of the coupling device 3 again radiated and in the optical waveguide L2, which is in a plane E3 below the plane El, in which the optical waveguide Ll is located, coupled.

In order to couple the decoupled from the optical waveguide Ll light beam in an optical waveguide L2, which is located in the lying above the planes E1 and E3 plane E2, will see according to the embodiment shown in Figure 6 between the optical waveguides Ll and L2 a plane-parallel

Plate 31b is introduced, which is aligned in the opposite direction with respect to the plane-parallel plate 31a shown in Figure 7. For coupling optical fibers Ll with Therefore, as shown in Fig. 6, optical fibers L2 arranged in different planes are alternately arranged in plane-parallel plates 31a and 31b with respect to their orientation.

With the arrangement shown in FIG. 6, it is possible to use optical waveguides which are arranged on a substrate 101 of a chip 100, for example with a spacing Dl = 62.5 μm, on optical fibers L2 with a diameter of 125 μm, which are as in FIG is shown arranged in different planes E2 and E3, to couple. The centers of the optical waveguides can be offset

V = 125 microns ^Xy l3 + 4 = 54μm _aufwe i _{sen. Be} in this embodiment, the centers of the optical waveguide L2 in the different planes E2 and E3 may be spaced by D2 = 108 microns each. The offset V results in the case of a thickness d of the plane-parallel plate, a refractive index n and a helix angle α of the plane-parallel plate

V = dxsin (α) x (1 - (cos (α) -r ^ (nxn-sin ² (α))) With an offset of V = 54 μm, a refractive index of n = 3.4 for plane-parallel

Plates of silicon, which have a helix angle of 45 °, results in a thickness d of the plane-parallel plate of about 97 microns.

Since, in the embodiment of the coupling device 3 shown in FIG. 6, no enlargement takes place through the optical system 30, the alignment or positioning of the plane-parallel plates is possible with little effort. A high-precision alignment of the plane-parallel plates is not required. In order to reduce power losses during the transmission of light by the coupling device, it is also possible, for example, in the case of the embodiment shown in FIG. guide lenses 12, as shown in Figures 2 and 3, are mounted in front of the optical waveguides Ll and L2. The lenses 12 may be integrated directly into the coupling device 3 or attached to the outer sides Sl and S2 of the coupling device 3. The lenses 12 can be attached to the guide pins 50, for example.

FIG. 8 shows a further embodiment of a coupling device 4 for coupling light from optical waveguides L1 and for coupling the light into optical waveguides L2, which are arranged in different planes E2 and E3. Instead of using plane-parallel plates 31a, 31b, an optical system 40 is used in the coupling device 4, which contains prisms 41a and 41b. In the embodiment shown in FIG. 8, a prism 41a is attached to the side S1 of the coupling device 4 and assigned to one of the optical waveguides L1. On the side S2 of the coupling device 4, a prism 41b oriented in the opposite direction to the prism 41a is arranged. In this case, each optical waveguide L2 is also assigned to one of the prisms 41b on the side S2.

When using prisms for beam deflection, the distance between the prisms can be variably selected. This makes it possible to remove the planes E2 and E3 far from each other, whereby the widening of the light cone between the prisms 41a and 41b is small.

The use of one of the coupling devices 1, 2, 3 or 4 makes it possible to couple together optical waveguides L1, which are arranged spatially differently on an optical chip 100, for example, than optical waveguides L2, which are connected as fiber ribbons to the chip. It In particular, it is possible to couple optical waveguides which are arranged in a ferrule, for example an MT ferrule, to optical waveguides which are embedded in a substrate of an optical chip and have a smaller spacing than the optical waveguides of the fiber band.

For beam modification in the coupling devices 1, 2, 3 and 4 lens systems 10, 20, 30 and 40 are provided, which may be formed of silicon, which is transparent in the light transmitted through the optical waveguides Ll and L2. The coupling devices 1, 2, 3 and 4 are suitable, for example, for the coupling of optical waveguides in optical backplane designs.

Claims

claims

1. Coupling device for coupling optical waveguides, comprising: - a first side (S1) for coupling first optical waveguides (L1) to the coupling device (1, 2, 3, 4),

a second side (S2) for coupling second optical waveguides (L2) to the coupling device (1, 2, 3, 4), - an optical system (10, 20, 30, 40) connected between the first and second side ( Sl, S2) of the coupling device is arranged,

- wherein the optical system (10, 20, 30, 40) a beam path of the first optical waveguides (Ll) coupled and coupled on the first side (Sl) in the coupling device light in response to an impact of the beam path on the optical System modified by a refraction of light such that the light at the second side (S2) is coupled out of the coupling device and coupled into the second optical waveguide (L2), wherein the first optical waveguide (Ll) arranged spatially different than the second optical waveguide (L2) are.

2. Coupling device according to claim 1, wherein the optical system (10, 20) comprises a lens (11, 21).

3. Coupling device according to one of claims 1 or 2, comprising: - further lenses (12) which are arranged between the lens (11) and the second optical waveguides (L2),

- Wherein each of the further lenses (12) in each case one of the second optical waveguide (L2) is assigned to that of the Lens (11) outgoing light in the respective one of the second lenses (12) associated with one of the second optical waveguide (L2) couple.

4. Coupling device according to claim 1, wherein the optical system (20) comprises a spherical lens (21).

5. Coupling device according to claim 4, - wherein the optical system (20) optical elements (22a, 22b), each containing optical waveguides (23a, 23b),

wherein the respective optical waveguides (23a, 23b) of the optical elements (22a, 22b) are coupled to the first or second optical waveguides (L1, L2),

- Wherein the optical elements (22a, 22b) each on one of the spherical lens side facing (S22a, S22b) are formed as a spherical half-shell.

6. Coupling device according to claim 1, wherein the optical system (30, 40), the beam path of the coupled from the plane in a (El) first optical waveguides (Ll) coupled light such that the light on the second side (S2) of the coupling device (3, 4) radiated and in the in different planes (E2, E3) arranged second optical waveguide (L2) is coupled.

7. Coupling device according to claim 6, wherein the optical system (30) comprises a plurality of plane-parallel plates (31a, 31b).

8. Coupling device according to claim 7, wherein the plurality of plane-parallel plates (31a, 31b) are arranged to each other in an alternating direction.

The coupling device of claim 6, wherein the optical system (40) includes a plurality of prisms (41a, 41b).

10. Coupling device according to claim 9,

- Wherein one of the prisms (41 a) on the first side (Sl) of the coupling device (4) one of the first

Optical waveguide (Ll) and another of the prisms (41b) on the second side (S2) of the coupling device is assigned to one of the second optical waveguide (L2),

- Wherein the one of the prisms (41 a) is aligned such that the light emerging from the one of the first optical waveguide (Ll) at the first side (Sl) of the coupling device in the one of the prisms (41 a) is irradiated and on the other of the Prisms (41b) is steered

- Wherein the other of the prisms (41b) is aligned so that that on the other of the prisms (41b) directed

Light emitted from the second side (S2) of the coupling device (40) and into which one of the second optical waveguide (L2) is coupled.

11. Coupling device according to one of claims 1 to 10, comprising: a guide pin (50) which protrudes on one of the first and second sides (Sl, S2) from the coupling device (1, 2, 3, 4), for fastening the coupling device on a component (100, 200) which contains the first and second optical waveguides (L1, L2).

12. Coupling device according to one of claims 1 to 11, comprising: a cavity (60) adapted to receive a guide pin (50) of a device (100, 200) containing said first and second optical fibers (L1, L2) for coupling said coupling means (1, 2, 3, 4) to be attached to the device (100, 200).

13. Coupling device according to one of claims 11 or 12, wherein the further lenses (12) on the guide pin (50) are attached.

14. Coupling device according to one of claims 1 to 13,

wherein the first optical waveguides (L1) are arranged on a first component (100) and the second optical waveguides (L2) on a second component (200),

- Wherein the first optical waveguide (Ll) on the first component (100) are arranged at a different distance from each other, as the second optical waveguide (L2) on the second component (200) are arranged.

15. Coupling device according to one of claims 1 to 14,

- wherein the first optical waveguide (Ll) on a first component (100) and the second optical waveguide (L2) on a second component (200) are arranged,

- Wherein the first optical waveguide (Ll) on the first component (100) in a plane (El) and the second optical waveguide (L2) on the second component (200) in different planes (E2, E3) are arranged.

16. Coupling device according to one of claims 14 or 15, wherein at least one of the first and second devices (100, 200) is formed as an optical chip.

17. Coupling device according to one of claims 14 or 15, wherein at least one of the first and second component (100, 200) is formed as a ferrule.

18. A system for coupling optical waveguides, comprising: - a first component (100) comprising first optical waveguides (L1),

a second component (200) comprising second optical waveguides (L2),

- A coupling device (1, 2, 3, 4) having a first side (Sl) at which the first component (100) to the coupling device (1, 2, 3, 4) is coupled, and with a second side (S2 ), at which the second component (200) is coupled to the coupling device (1, 2, 3, 4),

- Wherein the first optical waveguide (Ll) in the first component (100) on the first side (Sl) of the coupling device to each other spatially different than the second optical waveguide (L2) in the second component (200) on the second side (S2) of the coupling device are arranged

- wherein the coupling device (1, 2, 3, 4) comprises an optical system (10, 20, 30, 40),

- wherein the optical system (10, 20, 30, 40) a beam path of the first optical waveguides (Ll) coupled and coupled on the first side (Sl) in the coupling device light in response to an incident of the beam path to the optical System modified by a refraction of light so that the light at the second side (S2) is coupled out of the coupling device and coupled into the second optical waveguide (L2).

The system of claim 18, wherein the optical system (10, 20) includes a lens (11, 21).

20. The system of claim 19, comprising:

- Further lenses (12), which are arranged between the lens (11) and the second optical waveguides (L2),

- Wherein each of the further lenses (12) in each case one of the second optical waveguide (L2) is assigned to that of the

Lens (11) outgoing light in the respective one of the second lenses (12) associated with one of the second optical waveguide (L2) couple.

The system of claim 18, wherein the optical system (30) includes a plurality of plane-parallel plates (31a, 31b).

22. The system of claim 21, wherein the plurality of plane-parallel plates (31a, 31b) are arranged to each other in an alternating direction.

23. A method of coupling optical fibers, comprising:

Coupling out light from first optical waveguides (L1),

- coupling the light into a coupling device (1, 2, 3, 4),

Changing a beam path of the light coupled into the coupling device (1, 2, 3, 4) by means of an optical system (10, 20, 30, 40) as a function of an impact of the beam path on the optical system by a refraction of light in such a way, that the light coupled out of the coupling device is divided into second optical waveguides (L2) is coupled, wherein the first optical waveguide (Ll) on a first side (Sl) of the coupling device (1, 2, 3, 4) are arranged spatially different from each other, as the second optical waveguide (L2) on a second side (S2) of the Kopp - Lunging device are arranged spatially to each other.

24. Method according to claim 23, wherein the first optical waveguides (L1) on the first side (S1) of the coupling device (1, 2) are at a different distance from each other than the second optical waveguides (L2) on the second side (S2) Coupling device can be arranged.

25. The method of claim 23, wherein the first optical waveguide (Ll) on the first side (Sl) of the coupling device (3, 4) in a plane (El) and the second optical waveguide (L2) on the second side (S2) of the coupling device be arranged in different planes (E2, E3).