DE102013223230B4 - Connection element for multiple core fibers - Google Patents

Abstract

Connection element (1) for multiple core fibers (2) of an optical transmission system, comprising at least one main body (10) and a plurality of waveguides (31, 32, 33, 34, 35, 36, 37), which in the base body (10) in different planes (15, 16, 17), further comprising at least one mirror (5), which is adapted to deflect light from at least one waveguide (31, 32, 33, 34, 35, 36, 37) in a predeterminable direction.

Description

The invention relates to a connection element for multiple-core fibers of a fiber optic transmission system.

From practice it is known to modulate a digital data stream to an optical carrier signal and to spread this by means of an optical waveguide over a desired transmission path. The demands on the bandwidth of such optical transmission links are steadily increasing. The optical waveguide is usually a single-mode waveguide with a core and a cladding, wherein geometry and refractive index are selected so that only one mode propagates in the optical waveguide.

From DJ Richardson, JM Fini and LE Nelson: "Space Division Multiplexing in Optical Fibers", Nature Photonics 7 (2013) 354 is known to increase the bandwidth of an optical transmission system by using either multi-core optical fibers or multimode fibers, in which several optical modes can propagate. This allows the data transmission in the space-multiplex method, so that multiple data streams can be transmitted independently with different modes. As a result, the bandwidth of the optical transmission path can be increased.

However, these known space-multiplex methods have the disadvantage that at the input of the optical transmission path, the light of several laser diodes must be coupled into an optical fiber and at the end of the optical transmission path a plurality of propagatable modes must be coupled into associated photodetectors. These interfaces at the beginning and at the end of the optical transmission path have so far been very complicated to produce, require a lot of space and can not be reliably manufactured with consistent quality.

The DE 698 15 219 T2 shows an optically pumped fiber laser, in which optical fibers are guided in different planes, so that there is a different connection pattern at both ends.

The US 2010/0195965 A1 describes an arrangement converter in which input and output waveguides are arranged two-dimensionally. The respective geometric arrangement distinguishes between input and output.

Also the US Pat. No. 6,467,969 B1 discloses a coupler between a plurality of optical fibers, with which light between waveguides can be coupled with cores of different geometry and size.

The US 2004/0105648 A1 shows a connector for an optical backplane, in which a substrate is used with a plurality of grooves in which optical fibers are embedded.

Based on the prior art, the object of the invention is therefore to specify a connecting element for multiple-core fibers of an optical transmission system which does not have these features. The object is achieved by a connection element according to claim 1.

According to the invention, a connecting element for multiple-core fibers of an optical transmission system is proposed. The connection element has at least one main body. In the main body, a plurality of waveguides can be guided in different planes.

In the connector for connecting a multi-core fiber, the waveguides are arranged so that they can each receive light of a core of the multi-core fiber. For this purpose, the geometric arrangement of the waveguides on at least one end face of the connection element can be adapted to the geometric arrangement of a plurality of cores in a multiple-core fiber.

The plurality of waveguides of the connection element is then guided in the base body so that the light of individual waveguides is not influenced by the light of other waveguides and on the other hand a simple coupling with a laser diode and / or a photodiode is made possible. In some embodiments of the invention, the connection element can be set up in such a way that the geometric connection image of a multi-core fiber can be transferred into the geometrical connection image of components of optical communication technology known per se, such that conventional optical or optoelectronic components are also suitable for the new transmission technology in space-multiplexing. Method can be used. A conventional optical or optoelectronic component can be selected from a lens array, a photodiode array or a laser diode array.

In some embodiments of the invention, the main body of the terminal may have approximately the refractive index of the cladding of the multi-core fiber. Similarly, in some embodiments of the invention, the refractive index of the waveguides of the terminal may approximately correspond to the refractive index of the core of the cores of the multiple-core fiber. In these cases, the optical losses are minimized when coupling the light from the waveguide into the connection element and from the connection element into the waveguide. This allows efficient use of the available optical power.

In some embodiments of the invention, the terminal can be easily manufactured by depositing and patterning a plurality of layers of material. This allows manufacturing with well-known and established methods for manufacturing integrated optical components. For example, at first a layer of the base body can be produced. At least one waveguide may be formed on the surface of this layer by depositing another layer and then masking and etching the desired shape. The waveguide can then be covered with another layer of the material of the base body, before at least one further waveguide is produced on this layer. As a result of continuous deposition and structuring of layers, the base body with the embedded plurality of waveguides is thus produced in multiple layers. The waveguides can be performed in a straight line within a plane or describe within the body arcs or curves so as to emerge at other points of the body. In some embodiments of the invention, waveguides may also be routed across planes.

In some embodiments of the invention, the terminal may further include a substrate on which the body is disposed. In addition to the main body of the connection element, the substrate can carry further components, for example fastening devices for outgoing or incoming optical waveguides or optoelectronic or electronic components. In some embodiments of the invention, the substrate may include or consist of a silicon wafer. This allows the simple integration of CMOS electronics together with the connection element according to the invention.

In some embodiments of the invention, the substrate may include at least one receptacle for at least one multiple-core fiber. In some embodiments of the invention, the receptacle may be a V-groove or a U-groove. These grooves allow easy and accurate positioning of the optical fiber with respect to the connection element, so that the coupling between the waveguides of the connection element and the cores of the optical waveguide is optimized. The optical waveguide can be fixed in the receptacle by a clamping device or an adhesive, so that the waveguide no longer dissolves after positioning in the connection element, even under tensile loading during operation.

In some embodiments of the invention, the plurality of waveguides may be disposed on a first end face of the main body in accordance with the optical field distribution of a multiple core fiber. This optimizes the coupling of the optical power into the connection element. At a second, opposite end face of the base body, the plurality of waveguides can be arranged complementary to a laser diode array and / or a photodiode array. In these cases, the optical fiber butts against an end face of the connection element and the opposite end face of the main body of the connection element can be contacted with a laser diode array and / or a photodiode array. The connection element transfers the connection diagram of the diode array into the geometric arrangement or the connection diagram of the cores of the optical fiber. The connection diagram of the diode array can in this case be geometrically larger, so that sufficient installation space is available to arrange the active components and the connection wires of the diode array.

The connection element furthermore contains at least one mirror, which is set up to deflect light from at least one waveguide in a predeterminable direction. If mirrors are provided in the main body of the connection element, active components such as photodiodes or laser diodes can also be arranged on the lateral surface of the connection element. Since not only the end face of the connecting element is available for contacting the different cores of the waveguide, a larger number of laser diodes or photodiodes can be connected to the optical fiber or components with a larger installation space and possibly improved performance can be used.

In some embodiments of the invention, at least one photodiode and / or at least one laser diode and / or a diode array and / or further electronic components may be connected by an adhesive bond to an end face and / or lateral surface of the base body. This allows a particularly simple production of an active optical component, for example a receiver or a transmitter for optical signals. This only has to be connected to an optical fiber and a power supply, and is immediately ready for operation.

In some embodiments of the invention, the connection element may include at least one further optical component. As a result, beyond the mere contacting of the optical fiber with active or passive components, the connection element can assume additional tasks, For example, a signal coding or decoding or optical multiplexing.

In some embodiments of the invention, the further optical component may be selected from an array waveguide grating, a 90 ° hybrid, or a delay line interferometer. These components can be used, for example, for decoding an optical signal transmitted in wavelength division multiplexing or for decoding a phase-coded optical signal. Due to the complete integration into the connection element, a compact integrated optical component can be provided which only has to be completed with optoelectronic or electronic components known per se to form a fully functional system.

In some embodiments of the invention, the main body and / or the plurality of waveguides may consist of a polymer or contain a polymer. This allows a particularly simple production of the connection element in a production process known per se. For example, polymers can be applied in a spin-coating process and patterned by masking and etching.

In some embodiments of the invention, at least two waveguides can be arranged one above the other in the base body in different planes. In this way, a space-saving design of the connection element can be achieved, since a plurality of waveguides occupy only the base area of a single waveguide.

In some embodiments of the invention, an adhesive may be provided between the optical fiber and the terminal element which has approximately the refractive index of the terminal or optical fiber. Such an adhesive can further reduce coupling losses.

The mirror can be designed to deflect the beam path by about 90 °. In this way, light is directed from the end face to the lateral surface or from the lateral surface to the end face of a cuboid connecting element.

In some embodiments of the invention, at least one mirror may be obtainable by introducing a trench and applying a reflective coating. In some embodiments of the invention, the trench may have a vertical boundary surface and an inclined boundary surface. The inclined boundary surface and the vertical boundary surface may include an angle of approximately 45 ° to each other. The vertical boundary surface may be approximately parallel to an end face of the connection element.

The inclined boundary surface of the trench may be at least partially provided with a reflective coating. A reflective coating may be made, for example, of a multilayer system containing titanium and gold.

A trench for producing a mirror can be introduced, for example, by machining into the base body of the connecting element, for example by sawing or milling. In other embodiments of the invention, a mirror can be produced by etching a partial volume of the base body of the connection element.

In some embodiments of the invention, the terminal may be used to contact optical fibers of a data transmission network that space-multiplexes data. In other embodiments of the invention, the connection element can be used to contact fiber Bragg sensors, which can be used for measuring temperature and / or mechanical stresses.

Such fiber Bragg sensors can be written in optical fibers with multiple cores in order to achieve in this way a decoupling of temperature and force measurement or to increase the number of measuring points via a spatial multiplexing method. In this way, about 100 to about 1000 fiber Bragg gratings in an optical fiber can be independently read out. In other embodiments of the invention, about 500 to about 1000 fiber Bragg gratings may be disposed in an optical fiber which may be independently read out.

The invention will be explained in more detail below without limiting the general concept of the invention. It shows

1 the cross section of a multi-core fiber.

2 shows the first end face of a connection element according to the invention.

3 shows a first embodiment of the connecting element in cross section.

4 shows a second embodiment of the connecting element in cross section.

5 shows an embodiment of the connection element in plan view.

6 explains a third embodiment of the connecting element in cross section.

7 explains a fourth embodiment of the connecting element in cross section.

8th shows the connection element according to 6 in the supervision.

9 shows the connection element according to 7 in the supervision.

1 shows the cross section through a multi-core fiber, which is usable with the connection element according to the present invention. The optical fiber according to 1 has a coat 2 on. In the coat 2 are 7 cores 21 . 22 . 23 . 24 . 25 . 26 and 27 arranged. The cores each have a constant distance x ₁ , x ₂ , x ₃ and x ₄ to each other. The cores are arranged in three planes, which each have the distance y1 and y2 to each other. In some embodiments of the invention, these distances may be equal. In each core, an optical signal can be guided largely unaffected by the optical signals in the other cores. With a suitable choice of the refractive indices for the core and cladding, total reflection occurs at the respective boundary surface, so that the crosstalk between the cores can not be measured or is at least so slight that the noise components do not further disturb the signal transmission and readout.

In the 1 Cores shown can have a small diameter, so that in each case only a single optical mode is propagated in the core. The in 1 Cross-section optical waveguides can extend over a longitudinal extension of several 10 meters or several 100 meters or several 1000 meters.

The cores and the coat 2 In some embodiments of the invention, they may be polymeric material or glass. The illustrated geometry of the cores is only to be understood as an example. In other embodiments of the invention, more or fewer cores may be in the shell 2 be arranged.

The multi-core fiber according to 1 is to be understood as an illustrative example of the invention. The multiple-core fiber generates at its free end an optical field distribution whose spatial geometry is determined by the arrangement of the cores. In the same way, however, a multimode fiber with only a single core can also generate a spatial field distribution, which can be coupled in an analogous manner into a connection element having a plurality of waveguides.

2 shows the first face 11 a connection element 1 , The connection element 1 consists of a basic body 10 which is on an optional substrate 4 is arranged. The substrate 4 may for example contain glass or silicon and next to the main body 10 carry a plurality of optical, optoelectronic or electronic components. In this way, the connection element 1 Be part of an integrated optical component. In other embodiments of the invention, the substrate may be removed after fabrication of the terminal.

Also in the main body 10 are 7 waveguides 31 . 32 . 33 . 34 . 35 . 36 and 37 arranged. Also the waveguides in the main body 10 are in three levels 15 . 16 and 17 arranged. The relative distances of the waveguides 31 . 32 . 33 . 34 . 35 . 36 and 37 essentially correspond to the spacings of the cores of the multiple-core fiber. Also the distances of the levels 15 . 16 and 17 are adapted to the distances of the planes of the multiple-core fiber.

3 shows a section through the body 10 of the connection element 1 in one too 2 orthogonal section plane. As in 3 is shown, the waveguide 2 so to the first end face 11 of the basic body 10 be contacted that the waveguides 31 . 32 . 33 . 34 . 35 . 36 and 37 of the basic body 10 each an associated core 21 . 22 . 23 . 24 . 25 . 26 and 27 the multi-core fiber 2 face. In this way, the guided in the multi-core fiber light with low coupling losses in the connection element 1 or in the waveguides 31 . 32 . 33 . 34 . 35 . 36 and 37 of the connection element 1 coupled.

In the embodiment according to 3 may be the coupling of the multi-core fiber to the main body 10 done by gluing. The adhesive layer may have an adjusted refractive index to further reduce insertion losses. Also, the material of the main body 10 be selected so that this has approximately the same refractive index as the cladding 20 the multi-core fiber 2 , The same applies to the waveguides 31 . 32 . 33 . 34 . 35 . 36 and 37 of the connection element 1 and the cores 21 . 22 . 23 . 24 . 25 . 26 and 27 the multi-core fiber 2 ,

The production of the basic body 10 with the embedded waveguides 31 . 32 . 33 . 34 . 35 . 36 and 37 can be achieved by layering the material of the connection element on the substrate 4 respectively. For example, a polymeric material may be spin-coated or spray-coated on the substrate 4 deposited and subsequently cured.

4 shows a further embodiment of the invention. The same components are provided with the same reference numerals, so that the description is limited to the essential differences. As in 4 is apparent, is the substrate 4 larger than the base of the approximately rectangular body 10 of the connection element 1 , This provides the substrate 4 additional space for a recording device 45 , The receiving device may for example have a V or a U-groove, in which the jacket 20 the multi-core fiber 2 can be inserted to an exact positioning of the cores 21 . 22 . 23 . 24 . 25 . 26 and 27 the multi-core fiber opposite the waveguides 31 . 32 . 33 . 34 . 35 . 36 and 37 of the connection element 10 to enable.

5 shows the top view of the connection element 1 whose front side is in 2 and its longitudinal section in 3 is shown. Identical components are in turn provided with the same reference numerals, so that the description is limited to the essential differences. Shown again is the multiple core fiber 2 in the left part of the picture, which is at the first end face 11 of the basic body 10 of the connection element 1 is coupled. As 5 shows are the waveguides of the connection element 1 within their planes on their way from the first end face 11 to the second end face 12 pivoted so that the lateral distance of the waveguides changes. In this way, the connection of laser diodes or photodiodes or a laser diode array or a photodiode array on the second end face 12 be greatly facilitated because the connection pattern of the waveguide corresponds approximately to the connection diagram of the optoelectronic components. This connection pattern may be due to the geometric arrangement of the cores in the multiple core fiber 2 be different, with both connection pictures through the connecting element 1 be converted into each other. The pivoting of the waveguide in the connection element can be done in gentle arcs to minimize optical losses at the bends.

6 shows a third embodiment of the connecting element according to the present invention. The third embodiment is based essentially on the in 4 shown second embodiment of the invention. The same components are again provided with the same reference numerals.

The third embodiment differs from the previously described embodiments by the presence of mirrors 5 , Every mirror 5 consists of a ditch 51 with approximately triangular cross-section. The ditch 51 is by a vertical boundary surface 511 and an inclined boundary surface 512 educated. The vertical boundary surface 511 is approximately parallel to the first end face 11 of the basic body 10 , The inclined boundary surface 512 closes with the vertical boundary surface 511 approximately at an angle of 45 °. As a result, light from the waveguide at the inclined boundary surface 512 deflected by 90 °.

A ditch 51 For example, by machining with a micro mill or a micro saw or a broach into the body 10 be introduced. In other embodiments of the invention, a trench 51 also be produced by wet or dry chemical etching.

To ensure a good reflectivity, the inclined boundary surface 512 with a reflective coating 52 be provided. The coating 52 can be made for example by vapor deposition of titanium and subsequent vapor deposition of gold.

In 6 is shown that all beam paths through associated mirrors 5 be redirected. Around the waveguides at different depths of the main body 10 to capture, assign the respectively associated trenches 51 the mirror 5 different depths.

The presence of a mirror 5 allows optoelectronic components such as a photodiode 6 or a laser diode also on the lateral surface 13 of the connection element 10 to arrange. Because the lateral surface 13 due to the larger length of the main body 10 has a larger area than the second end face 12 , This additional space can be gained. Alternatively, individual waveguides on the second end face 12 lead and other waveguides as in 6 shown to the lateral surface 13 be redirected.

7 shows a fourth embodiment of the invention. Shown are three mirrors 5a . 5b and 5c , which are each the waveguides of a plane 15 . 16 and 17 to capture. Instead of grooves 51 Provide different depth, has the body 10 a stepped basic form with a first step 14a and a second stage 14b on. The grooves are introduced into the steps, each with the same depth.

Based on 8th and 9 again different geometries of the waveguides are explained in their associated levels. In 8th the waveguides are pivoted, as already described by 5 was explained in more detail. Through the mirror 5a . 5b and 5c which the in 6 Having shown geometry, the optical paths of the respective waveguide at different locations of the lateral surface 13 of the connection element 10 decoupled. The resulting pattern may be due to the position of the mirror 5a . 5b and 5c as well as the position of the waveguides are optimized so that the desired optical or optoelectronic components on the connection element 1 can be attached.

9 shows three mirrors 5a . 5b and 5c in the supervision, which the in 7 having shown geometry. Accordingly, the three trenches of the mirrors are the same depth and have the same width.

As in 9 Furthermore, it can be seen that the waveguides extend in a straight line through the connection element 1 , As a result, space can be saved, since a plurality of waveguides can be performed one above the other and thus occupies the same base in the integrated optical component. In the illustrated embodiment, these are the waveguides 31 and 36 such as 32 and 37 , which are each arranged one above the other.

Due to the different levels of the waveguides and the respective mirror associated with one level, the light of these waveguides still occurs at different locations of the lateral surface 13 on. This in 9 Scheme shown, for example, the arrangement of the light entry surface of a photodiode array correspond, so that the light from the 7 Cores of multiple-core fiber 2 over the connection element 1 can be coupled into an associated photodiode array.

Of course, the invention is not limited to the embodiments shown in the figures. The above description is therefore not to be considered as limiting, but as illustrative. The following claims are to be understood as meaning that a named feature is present in at least one embodiment of the invention. This does not exclude the presence of further features. If the description or the claims define 'first' and 'second' features, this serves to distinguish similar features without ranking.

Claims (11)

Connection element ( 1 ) for multiple-core fibers ( 2 ) of an optical transmission system, with at least one main body ( 10 ) and a plurality of waveguides ( 31 . 32 . 33 . 34 . 35 . 36 . 37 ), which in the basic body ( 10 ) in different levels ( 15 . 16 . 17 ), further comprising at least one mirror ( 5 ), which is adapted to light from at least one waveguide ( 31 . 32 . 33 . 34 . 35 . 36 . 37 ) in a predeterminable direction. Connection element according to claim 1, further comprising a substrate ( 4 ), on which the basic body ( 10 ) or further comprise a substrate ( 4 ) containing or consisting of a silicon wafer and on which the base body ( 10 ) is arranged. Connection element according to claim 2, characterized in that the substrate ( 4 ) at least one recording ( 45 ) for at least one multiple-core fiber ( 2 ) contains. Connection element according to one of claims 1 to 3, characterized in that the plurality of waveguides ( 31 . 32 . 33 . 34 . 35 . 36 . 37 ) at a first end face ( 11 ) of the basic body corresponding to the optical field distribution of a multi-core fiber ( 2 ) is arranged. Connection element according to one of claims 1 to 4, characterized in that the plurality of waveguides ( 31 . 32 . 33 . 34 . 35 . 36 . 37 ) on a second end face ( 12 ) of the basic body ( 10 ) is arranged complementary to a laser diode array and / or a photodiode array. Connecting element according to one of claims 1 to 5, characterized in that at least one mirror ( 5 ) is adapted to light from at least one waveguide ( 31 . 32 . 33 . 34 . 35 . 36 . 37 ) to deviate by 90 °. Connecting element according to one of claims 1 to 6, characterized in that at least one mirror ( 5 ) by introducing a trench ( 51 ) and applying a reflective coating ( 52 ) is available. Connecting element according to one of claims 1 to 7, characterized in that at least one laser diode ( 7 ) and / or at least one photodiode ( 6 ) on a lateral surface ( 13 ) of the basic body ( 10 ) is arranged. Connecting element according to one of claims 1 to 8, further comprising at least one further optical component, which is selected from an arrayed waveguide grating, a 90 ° hybrid or a delay line interferometer. Connecting element according to one of claims 1 to 9, characterized in that the basic body ( 10 ) and / or the plurality of waveguides ( 31 . 32 . 33 . 34 . 35 . 36 . 37 ) consists of a polymer or contains a polymer. Connecting element according to one of claims 1 to 10, characterized in that at least two waveguides ( 31 / 36 . 32 / 37 ) in the main body ( 10 ) in different levels ( 15 . 17 ) are arranged one above the other.

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