WO2008022609A1

WO2008022609A1 - Optical coupling element

Info

Publication number: WO2008022609A1
Application number: PCT/DE2007/001181
Authority: WO
Inventors: Roland Mödinger; Jan Kostelnik; Volker TÜRCK; Axel Beier
Original assignee: Erni Electronics Gmbh; Siemens Ag; Würth Elektronik GmbH & Co. KG
Priority date: 2006-08-24
Filing date: 2007-07-04
Publication date: 2008-02-28
Also published as: DE102006039601A1

Abstract

An optical coupling (3) for the end-face optical coupling of waveguides (11, 12) of a first two-dimensional waveguide array having m´n waveguides to the waveguides (21, 22) of a second two-dimensional waveguide array having m´n waveguides, wherein m = 2 and n = 2, and wherein the end-face ends (15, 24) of the waveguide arrays are arranged at an angle to one another, is characterized by a plane mirror surface (310) which is arranged at an angle and by which the light of the first waveguide array is deflected onto the second waveguide array, and it comprises, assigned thereto, m rows - running parallel - of at least n lenses (311, 312, 321, 322) arranged in the beam path of the deflected light.

Description

Erni-Elektro-Apparate GmbH. Seestraße 9, 73099 Adelberq

Siemens AG. Witteisbacherplatz 2. 80333 Munich

Würth Elektronik GmbH & Co. KG. Salzstraße 21. 74676 Niedernhall

Optical coupling element

State of the art

The invention is based on an optical coupling element for frontal optical coupling of the waveguides of a first two-dimensional waveguide array with the waveguides of a two-dimensional waveguide terarrays according to the preamble of claim 1. The present invention is also an optical coupling arrangement with two two-dimensional waveguide arrays and a optical coupling element according to the preamble of claim 13.

To achieve high transmission rates in communication technology, data is increasingly transmitted via parallel connections. In optoelectronic transmission methods, the data is transmitted in parallel via a plurality of optical channels. For this purpose, two or more optical layers of optical waveguides are integrated in optical printed circuit boards, wherein each optical layer comprises a one-dimensional array of optical waveguides. Such optical circuit boards can be used, for example, in switching be used in which high transmission rates must be realized and a high degree of optical parallelism of the data transmission paths is advantageous.

To now, for example, an optical circuit board with a two-dimensional waveguide array, also referred to as 2D printed circuit board to couple with a 2D backplane circuit board, such as a cabinet, an arrangement of the two circuit boards at an angle to each other is necessary. An optical coupling of two two-dimensional waveguide arrays, which are oriented at an angle, in particular perpendicular to one another, is also required, for example, in the coupling of an optical transmitting or receiving module with two-dimensionally arranged optical transmitters or receivers to a 2D optical printed circuit board. Another application of such a coupling is the coupling of electronic assemblies, for example electronic chips with two-dimensionally arranged optical inputs and / or outputs to two-dimensional optical waveguide arrays.

From the unpublished European patent application no. 05090102.4 a generic optical coupling element is apparent, which has parallel rows of n mirror areas in each case, wherein the light of the first waveguide array is deflected by the mirror areas on the second waveguide array and in each case a pair of waveguides of the first and second waveguide arrays is assigned a mirror area for Lichtkoppiung. In addition, this non-prepublished European patent application discloses a generic optical coupling arrangement in which such a coupling element is used for the front-side optical coupling of the waveguides of the first waveguide array with the waveguides of the second waveguide array. This optical coupling element is characterized in that it has m parallel rows of n mirror areas in each case. The light of the first waveguide array becomes the second through the plurality of mirror regions Waveguide array deflected. In this case, in each case one waveguide pair of the first and the second waveguide array is assigned a mirroring region for coupling light. The coupling element is attached to the ends of the optical waveguide of a two-dimensional array and allows light coupling for each optical waveguide, each with associated optical waveguides of a further two-dimensional array arranged at an angle, in particular vertically. The problem with this coupling element is that different image scales are required for the different channels, which are each formed by different layers of the two-dimensional waveguide arrays, which must be realized by the deflection mirrors with curved surfaces. These mirrors are for example designed as a concave mirror with a spherical shape or in the form of a paraboloid of revolution. By mapping errors so coupling losses can occur, which in turn can have high transmission losses.

Disclosure of the invention

Advantages of the invention

The optical coupling element according to the invention with the features of independent claim 1 has the advantage that identical magnifications can be used for the two channels, each realized by the superimposed in the optical board two-dimensional waveguide arrays. By means of the at least n lenses, the imaging scale can be adapted in each case to optical waveguide geometries. This has the great advantage that only slight coupling losses occur due to adapted mappings.

The features listed in the dependent claims advantageous refinements and improvements of the specified in the independent claim optical coupling element are possible. Thus, a very advantageous embodiment provides that in the beam path of the deflected light 2n optical lenses are arranged, whose first part is associated with a first, coupled to the front end of the first waveguide array input / output coupling surface and the second part of a second with the front end is assigned to the second waveguide array coupling input / output coupling surface. By these two lenses, the adaptation of the imaging scale to the optical fiber geometries and thus a reduction of the coupling losses is particularly advantageous.

In principle, the lenses and the angular plane arranged mirror surface can be realized by different components. However, an embodiment which is very advantageous not only in terms of production but also in particular with regard to the assembly provides that the coupling element is a light-guiding body, on whose first surface facing the first coupling surface, the first part of the optical lenses is arranged , Wherein the second part of the optical lenses is arranged on the second, the second input / outcoupling surface facing surface and arranged on the third surface of the mirror or is formed. In this way, all the optical elements are formed integrally with the coupling element, which thus forms a monolithic block. This design has the advantage that the coupling element can be adjusted and fixed together with the lenses and the mirror as a whole. The lenses may be formed integrally with the photoconductive body, but may also be attached as a separate part to the photoconductive body, e.g. be glued on.

In principle, a coupling of arranged at any angle waveguide arrays is possible. Preferably, the angle between the first and the second input / output surface is 90 °. The mirror is in this case both the first input / output surface as well as the second EitWAuskoppelfläche inclined at an angle of 45 °.

The first part of the lenses as well as the second part of the lenses can be attached in principle, for example, by gluing on the first or second surface of the optical coupling element. However, in order to exclude at the splice transition losses and the like, and also with a view to a simple production provides an advantageous embodiment that both the first and the second part of the lenses are part of the photoconductive, the coupling element forming body, the light-conducting body in the Lenses is thus formed accordingly.

In order to achieve optimum images, the lenses are preferably collecting lenses, which may have spherical or aspherical end faces.

The light-conducting body is preferably made of a high-refractive glass, plastic or a similar, transparent to the light rays used here material. The refractive index of the high refractive index glass is preferably n ≥ 1.8.

The invention also relates to an optical coupling arrangement comprising a first two-dimensional waveguide with mxn waveguides, a second two-dimensional waveguide with mxn waveguides, wherein m ≥ 2 and n ≥ 2 and the front ends of the waveguide arrays are arranged at an angle to each other a pre-described coupling element for the frontal optical coupling of the waveguides of the waveguide array is used with the waveguides of the second waveguide array.

In this case, an air space is preferably arranged between the end faces of the first part of the optical lenses and the first input / output surface or the front end of the first waveguide array. Similarly, it is preferable between the end faces of the second part of the optical lenses and the Second input / output surface or the front end of the second wave lenleiterarrays also arranged an air space. The two air spaces are preferably interconnected.

In another embodiment, it is provided that an immersion medium is arranged between the end faces of the first part of the optical lenses and the front end of the first waveguide array. Also, between the end faces of the second part of the optical lenses and the front end of the second waveguide array, an immersion means may be provided. The two immersion means may in particular be identical, that is to say be formed in one piece. The immersion agent is, for example, an adhesive or a transparent potting material. The immersion agent protects the optical paths from dust and dirt, provides an optical compensation of irregularities on the waveguide end faces and also fixes the coupling element in terms of its location. The immersion agent in this case has a refractive index which is smaller than the refractive index of the light-conducting body.

The coupling element may be formed as a separate part. It is also possible that it is part of a coupling unit or of a functional part which comprises the first or the second waveguide array.

The first and / or the second waveguide array are realized in preferred embodiments in a multilayer optical circuit board, in an optical transmitting or receiving module with two-dimensionally arranged optical transmitters and / or receivers or in an electrical assembly with two-dimensionally arranged inputs and / or outputs.

Brief description of the drawings

Embodiments of the invention are illustrated in the drawings and explained in more detail in the following description. Show it

1 shows schematically in section an embodiment of a coupling arrangement for coupling two two-dimensional waveguide arrays and

Fig. 2 is an enlarged view of the coupling element of the coupling arrangement shown in Fig. 1.

Embodiments of the invention

FIG. 1 shows a coupling arrangement with a two-layered optical printed circuit board 1, a waveguiding functional element 2 and an optical coupling element 3 for the optical coupling of optical printed circuit board 1 and functional element 2.

The two-layer optical circuit board has in two superimposed, at a distance a from each other, mutually parallel layers each have a one-dimensional array of n optical fibers 11, 12, of which the sectional view of FIG. 1 each show an optical waveguide 11, 12. The other optical waveguides 11, 12 are respectively arranged in front of and behind the plane of the drawing. The optical circuit board 1 therefore has 2xn waveguides forming a two-dimensional waveguide array. If the circuit board has m layers of such waveguides, where m ≥ 2, then the circuit board 1 comprises a waveguide array of mxn waveguides. The individual waveguides are advantageously optically integrated in the optical printed circuit board 1 in a manner known per se.

The functional element 2 also has two spaced apart from each other layers of a respective one-dimensional array of n- Lichtwellenleitem 21, 22, wherein the sectional view of Fig. 1, in turn, only one of the optical waveguides 21, 22 shows each layer. In that case, m layers of optical waveguides are provided in the functional element m, the functional element 2 comprises a waveguide array with mxn waveguides.

The functional element 2 is, for example, a part or partial area of a further two-dimensional printed circuit board, a part or partial area of a two-dimensional optical transmitting and / or receiving module, a part or partial area of an electrical assembly with optical inputs and / or outputs or a part or partial area of a coupling unit which is connected to another functional element.

In the following, the specific training and the functionality of the functional element 2 or connected to the functional element 2 modules and assemblies will not be discussed, as in the present invention aliein on the coupling between the respective optical waveguides of the two two-dimensional arrays of optical circuit board 1 and functional element arrives. It will therefore not be discussed in the following, where lead the waveguide shown in each case and which mechanisms light of which components and modules is switched on and / or out. The present invention provides no restrictions in this regard. In the following, only the coupling arrangement and the coupling element will be described.

The optical circuit board 1 and the functional element 2 are arranged relative to one another such that the respective optical waveguides 11, 12, 21, 22 extend substantially perpendicular to one another. The optical circuit board 1 has a recess 13 into which a partial region 25 of the functional element 2 protrudes. The functional element 2 has lateral projections 23, with which it is supported on the surface 14 of the optical printed circuit board 1. The support is shown in Fig. 1 only schematically and can be realized in many ways. Since the thickness of the printed circuit board 1 can sometimes vary considerably due to tolerances in the printed circuit board manufacturing technology, after adjusting the functional element 2 and preferably already connected to this coupling element 3 on the circuit board 1 is first an adjustment, in particular an active adjustment with respect to the circuit board. 1 to align with the respective waveguides. In the adjusted state, the functional element 2 is then fixed, for example by an adhesive against the printed circuit board 1.

Through the recess 13 of the circuit board 1, the waveguide array with the two 2xn waveguides 11, 12 exposed, the end faces of the waveguides 11, 12 are substantially perpendicular to the surface 14 of the circuit board and substantially perpendicular to the longitudinal extension of the waveguides 11, 12 extend , The waveguides 11, 12 of the two-dimensional array terminate at an end face 15 of the optical printed circuit board, which is defined by the recess 13.

As shown in Fig. 1, the end face 15 forms the lateral end of the optical circuit board 1, wherein the coupling element 3 adjoins this front end 15 of the optical circuit board. The illustrated in Fig. 1 further portion 1 'of the circuit board 1 is formed in this case only as a support element without waveguide.

Correspondingly, the functional element 2 also has an end face 24 on which the end faces of the waveguides 21, 22 of the further two-dimensional waveguide array are exposed.

By the coupling element 3 is now an optical coupling between the optical waveguides 11, 12 of the two-dimensional optical waveguide array of the optical circuit board 1 and the optical waveguides 21, 22 of the two-dimensional optical waveguide array of the functional element 2, at an angle in the illustrated embodiment at an angle of 90 ° arranged to each other, possible. It is understood that the invention is not limited to the arrangement of the two weakening conductor arrays at a right angle, but that with a corresponding arrangement purely in principle any angle can be realized.

The optical coupling element 3 is formed as shown in FIG. 1 as a separate part. However, the invention is not limited to this, but rather it is also possible that the coupling element 3 is part of the functional element 2 or a coupling unit which is coupled to a functional element 2. It may for example be formed in one piece with the functional element 2 of FIG. 1, which may then represent a coupling unit for another functional element such as an optical module or an electrical assembly or the like.

The coupling element 3 is a light-conducting body in the form of a prism made of a high refractive transparent plastic or of a high refractive index glass. It can also consist of another transparent material for the wavelengths considered. The prismatic coupling element 3 has a first input / output surface 33, which is coupled to the front side 15 of the optical printed circuit board 1 and a second input / output surface 34, which is coupled to the end face 24 of the functional element 2. The two input / Auskoppeiflächen 33, 34 of the coupling element 3 are arranged at an angle to each other, which corresponds to the angle at which the optical circuit board 1 and the functional element 2 are arranged to each other - in the considered embodiment, this angle corresponds to a right angle. It should be noted that the input / output surfaces 33, 34 in Fig. 1 end in an air space, which is in each case arranged between the light guide body 3 and the waveguides 11, 12 and 21, 22. The invention is not limited thereto. Rather, it can be provided that the said air space between the input / output surfaces 33, 34 and the surfaces of the light-conducting body, which forms the coupling element 3, also to be described below, also with an immersion medium forming a filling body, For example, a photoconductive adhesive or a potting or the like can be filled.

Such an immersion agent performs the following functions: a) the protection of the optical paths from dust and dirt, b) an optical compensation of irregularities at the waveguide end faces, which may be due to the limited quality of the surface treatment of the printed circuit board 1, for example, when milling the recess 13 from the optical circuit board 1, c) fixing the position of the coupling element 3rd

In the event that such an immersion body is arranged between the light-conducting body 3 and the front end 15 of the optical waveguides 11, 12 or 21, 22, the input / outcoupling surfaces 33, 34 each form planar surfaces. In the event that air is arranged between the end faces 15 or 24 of the optical waveguides 11, 12 or 21, 22 and the light-conducting body 3, this air space is to some extent added to the coupling arrangement and to that extent form the input / output coupling surfaces 33, 34 so to speak, fictitious bounding surfaces, which are subsequently also referred to in the sense of a uniform description.

The prismatic coupling element 3 has three surfaces 301, 302 and 303 extending perpendicular to the plane of the drawing. On a surface 303, which is arranged in each case inclined at the same angle to the first input / output surface 33 and the second input / output surface 34, which corresponds to half the angle at which the functional element 2 is arranged opposite the optical circuit board 1, shown Case 45 °, a mirror 310 is arranged.

The first surface 301 is arranged at a distance di parallel to the first input / outcoupling surface 33, the second surface 302 is parallel to the first surface 301 second EirWAuskoppelfläche 34 and arranged at a distance d ₂ of this input / output surface 34. On the first surface 301, lenses 311, 312 are formed whose optical axes coincide with the optical axes of the waveguides 11, 12.

On the surface 302 lenses 321, 322 are arranged, the optical axes of which coincide with the optical axes of the waveguides 21, 22. The distances di and d ₂ are insofar defined by the optical axes of the waveguides 11, 12 and 21, 22 and the size and arrangement of the lenses 311, 312, 321, 322.

In FIG. 2, the coupling element 3 and the lenses 311, 312, 321, 322 arranged thereon and the mirror 310 together with beam paths S1, S2 are shown enlarged. The mirror 310 arranged at an angle of 45 ° both to the first input / output surface 33 and to the second output surface 34 is realized, for example, by metallizing the surface 303. However, the mirror 310 can also be arranged or fastened on the surface 303 in any other known manner.

On the surface 301 are two curved end faces 313, 314, which form the lenses 311, 312, are provided, whereas on the surface 302 curved end faces 323, 324, which form the lenses 321, 322 are arranged. The end faces 313, 314, 323, 324 are curved in such a way that the lenses 311, 312, 321, 322 are converging lenses. The end faces 313, 314, 323, 324 can be curved spherical or aspherical for this purpose. By this converging lenses 311, 312, 321, 322 parallel beam paths S1, S2, which are deflected by the plane deflection mirror 310, realized. As a result, axis-parallel beams are again parallel to the axis after imaging, which enables optimum NA matching for the optical fiber coupling.

The light-conducting body 3, which can also be referred to as a deflection block, preferably consists-as mentioned above-of a high refractive material which is transparent for the wavelengths of light in question, for example a high refractive index glass which ideally has a refractive index of n> 1.8.

The lens elements, that is to say the lens surfaces 313, 314, 323, 324, which form the converging lenses 311, 312, 321, 322, are either formed together with the light-conducting body 3 in one piece therewith or produced as separate parts and, for example, on the surfaces 301 or 302 glued.

In the event that between the end faces 313, 314 and 323, 324 and the first input / output surface 33 and the second input / output surface 34, an air space exists, the light-conducting body 3 in a manner not shown in the cavity 13 after fixed to his adjustment. In the event that said space is filled by a filling adhesive acting as an immersion or filled by another body, this filler body must have a lower refractive index than that of the photoconductive body 3 and the converging lenses 311, 312, 321, 322, so that Illustration of the light rays through the converging lenses 311, 312, 321, 322 is possible.

Claims

claims

1. Optical coupling element (3) for the frontal optical coupling of waveguides (11, 12) of a first two-dimensional waveguide terarrays with mxn waveguides with the waveguides (21, 22) of a second two-dimensional waveguide array with mxn waveguides, where m> 2 and n ≥ 2, and wherein the front ends (15, 24) of the waveguide arrays are arranged at an angle to each other, characterized by an angularly arranged plane playing surface (310), by which the light of the first waveguide array is deflected onto the second waveguide array, and associated with these m parallel rows of at least n, arranged in the beam path of the deflected light lenses (311, 312, 321, 322).

2. Coupling element (3) according to claim 1, characterized in that in the beam path of the deflected light 2n optical lenses are arranged, the first part (311, 312) of a first, coupled to the front end (15) of the first waveguide array input / Decoupling surface (33) is assigned, and the second part (321, 322) of a second, with the front end (24) of the second waveguide array can be coupled coupling input / output surface (34).

3. coupling element (3) according to claim 2, characterized in that the coupling element (3) is a light-conducting body, at the first, the first input / outcoupling surface (33) facing surface (301) of the first part of the optical lenses (311 , 312) is arranged on the second, the second input / outcoupling surface (34) facing surface (302) of the second part of the optical lenses (321, 322) is arranged and on the third surface (303) of the mirror (310) is arranged.

4. Coupling element (3) according to claim 3, characterized in that the angle between the first and the second input / output coupling surface (33, 34) is 90 °.

5. coupling element (3) according to claim 3, characterized in that the mirror (310) is inclined to both the first input / output surface (33) and the second input / output surface (34) at an angle of 45 °.

6. coupling element (3) according to any one of the preceding claims, characterized in that both the first part of the optical lenses (311, 312) and the second part of the optical lenses (321, 322) are part of the light-conducting body.

7. Coupling element (3) according to claim 6, characterized in that both the first part of the optical lenses (311, 312) and the second part of the optical lenses (321, 322) are integrally formed with the light-conducting body.

8. Coupling element (3) according to claim 6, characterized in that both the first part of the optical lenses (311, 312) and the second part of the optical lenses (321, 322) are attached as separate parts to the light-conducting body.

9. Coupling element (3) according to any one of the preceding claims, characterized in that both the first part of the optical lenses (311, 312) and the second part of the optical lenses (321, 322) are converging lenses (313).

10. Coupling element according to claim 9, characterized in that the collecting lenses (311, 312, 321, 322) have aspherically curved end faces (313, 314, 323, 324) or spherically curved end faces.

11. Coupling element (3) according to one of the preceding claims, characterized in that it consists of a high-refractive glass or plastic.

12. Coupling element (3) according to claim 11, characterized in that the high-index glass has a refractive index n> 1.8.

13. An optical coupling arrangement with a first two-dimensional waveguide array with mxn waveguides (11, 12) and a second two-dimensional waveguide array with mxn waveguides (21, 22), where m ≥ 2 and n> 2 and the front ends of the Wellenlei Terarrays are arranged at an angle to each other, characterized by a coupling element (3) for the frontal optical coupling of the waveguides of the first waveguide array with the waveguides of the second waveguide array according to one of the preceding claims 1 to 12.

14. Coupling arrangement according to claim 13, characterized in that the first input / output coupling surface (33) is associated with the front end (15) of the first waveguide array and the second input / output surface (34) with the front end (24) of the second waveguide array ,

15. Coupling arrangement according to claim 13 or 14, characterized in that between the end faces (313, 314) of the first part of the optical lenses (311, 312) and the first input / output coupling surface (33) an air space is arranged.

16. Coupling arrangement according to claim 13 or 14, characterized in that between the end faces (323, 324) of the second part of the optical lenses (321, 322) and the second input / output coupling surface (34) an air space is arranged.

17. Coupling arrangement according to claim 15 and 16, characterized in that between the end faces (313, 314) of the first part of the optical lenses (311, 312) and the first input / output surface (33) arranged air space and between the end faces (323, 324) of the second part of the optical lenses (321, 322) and the second input and output surface (34) arranged air space are each interconnected.

18. Coupling arrangement according to claim 13 or 14, characterized in that between the end faces (313, 314) of the first part of the optical lenses (311, 312) and the first input / output coupling surface

(33) a filling body, in particular a filling adhesive with a lower refractive index than that of the coupling element (3) is arranged.

19. Coupling arrangement according to claim 13 or 14, characterized in that between the end faces (323, 324) of the second part of the optical lenses (321, 322) and the second input / output coupling surface

(34) a filling body, in particular a filling adhesive with a lower refractive index than that of the coupling element (3) is arranged.

20. Coupling arrangement according to claim 18 and 19, characterized in that between the end faces (313, 314) of the first part of the optical lenses (311, 312) and the first input / output surface (33) arranged filling body and between the end faces (323, 324) of the second part of the optical lenses (321, 322) and the second input and output surface (34) arranged from each filler consist of the same material, in particular are integrally formed.

21. Coupling arrangement according to one of claims 13 to 20, characterized in that the coupling element (3) is designed as a separate part.

22. Coupling arrangement according to one of claims 13 to 20, characterized in that the coupling element is part of a coupling unit or a functional part comprising the first or the second waveguide terarray.

23. Coupling arrangement according to one of claims 13 to 22, characterized in that the first and / or the second waveguide array are realized in an optical circuit board (1), in an optical transmitting or receiving module with two-dimensionally arranged optical transmitters or receivers or in one electrical assembly with two-dimensionally arranged optical inputs and / or outputs.