DE3324161A1 - Optical coupler - Google Patents

Abstract

It is provided to use a graded-index lens of n . 1/4 pitch length as coupling device for an optical coupler for dividing the luminous flux of an optical fibre into component luminous fluxes. In this case, the input and output optical fibres are arranged on the front surface of the lens, while the other end of the lens is provided with reflecting surfaces. Obliquely inclined reflecting surfaces are provided, whose inclination determines the imaging locations of the reflected light beams on the front surface of the lens, and whose number determines the number of the coupling gates. The lens end provided for reflection is provided with silvering.

Description

Optical coupler

The invention relates to an optical coupler for dividing the Light strands of an optical fiber in partial flows or to combine partial flows to a single luminous flux, as well as a method for producing such a Coupler.

Optical couplers are used for signal distribution in fiber optic networks optical messaging is used.

The luminous flux of a fiber should be reduced to two (T-couplers) or more (Star coupler) Fibers are divided, or a certain number of Streams of light are combined into a single stream of light.

There are T or. Stern-Koppier known that with the help of the most diverse Technologies are produced. They range from merging or gluing two or more fibers up to the use of several optical components, such as microlenses and mirrors. (See e.g. W. Ludolf: '4 Basics of optical transmission technology, part 5.

Optical Coupler ", Technisches Messen, December 12, 1982, page 471, or M. Hirai and N. Uchida: "Melt splice of multimode optical fiber with an electric arc ", Electronics Letters 13 (1977), page 123.) For the practical application of the different coupler principles is on the lowest possible transmission loss, a reproducibly adjustable division ratio, a mode-independent one Coupling and a production method that is as simple as possible and that can be automated.

The present invention is based on the object of an optical To create couplers for fiber optic systems that contain as many of the above as possible Assessment criteria positively combined.

This task is solved in a technically advanced way by that a gradient lens n 1/4 pitch length is used as a coupling element, that one end of the gradient lens in a partial area at an angle to Lens end surface is ground that the end of the provided with the bevel Gradient lens is mirrored, and that on the front surface of the gradient lens the incoming and outgoing optical fibers in the imaging area of the respective Mirror surface are arranged.

Another advantageous embodiment of the invention provides that the gradient lens with several, facet-like arranged bevel surfaces / Mirror surfaces is provided.

An advantageous manufacturing process for such optical couplers is explained in more detail in process claim 3.

The advantages achieved with the invention are in particular: that for dividing the luminous flux of an optical fiber into two or more substreams only a single gradient lens is required. It is possible to use different To couple fiber types with each other, including those with different core diameters.

Since the surface area ratio is from non-sanded to sanded End face of the gradient lens, the division ratio of the light, can this very easily and in almost any size by appropriate dimensioning the ground surface can be set, i.e. both symmetrical and highly asymmetrical couplers can also be produced.

It is special for the manufacture of such optical couplers advantageous if a large number of lenses are held in a suitable holder, be sanded and then mirrored in a single operation.

The light-conducting fibers can then be used as a whole adjusted and fastened in front of the respective lens (e.g. by potting).

In particular, thanks to this possibility, a large number of lenses at the same time to grind, to mirror and the fibers as a whole in front of the respective lens to adjust and fasten, the proposed method is particularly suitable for the simple, serial production of kampakten T or star couplers with arbitrarily selectable coupling ratio.

An embodiment of the invention is shown in the drawing and is explained in more detail below.

1 shows a T-coupler and FIG. 2 shows a star coupler.

1 shows an optical coupler designed as a T-coupler shown, which consists essentially of a 1/4 pitch long gradient lens 1 with optical fibers 3, 4, 5 arranged on the front surface 2 thereof.

The other end of the gradient lens has the one parallel to the front surface End face 6 on and in the upper area of this lens end in the illustration the lens is provided with a flat, inclined surface 7.

This surface 7 is at an acute angle 4 to the end surface 6 arranged.

The surfaces 6 and 7 of the gradient lens, i.e. the entire lens end surface, are provided with a mirror coating 8, the mirror coating by vapor deposition, chemical application or other methods known per se can be generated.

The optical fiber 3 shown in Fig. 1 leads, for example, the In the lens entering (coupled) Lichtstram 3a, which on the outgoing Optical fibers 4, 5 are to be divided. Caused by their doping profile the 1/4 pitch long gradient lens an expansion of the coupled light beam 3 a in such a way that a parallel light beam is present on the mirrored end face 6. The partial light stream 3a 'is reflected by reflection at the end face 6, and deflected on the second pass through the lens so that it is in the area of the outgoing Optical fiber 5 is focused on the lens front surface 2, here again parallel emerges from the lens and is coupled into the fiber 5.

Part of the luminous flux 3a hits the as part of the light stream 3a ″ at the angle 2 arranged end face 7.

Here, too, there is a reflection of the light stream and due to it the inclination of the mirror surface is this luminous flux through the second pass the lens is deflected and also refocused so that it is in the area of the optical fiber 4 impinges on the front surface of the lens and here again parallel from the Lens emerges and is coupled into the fiber 4.

The surface 7 provided at the angle to the lens end surface becomes preferably produced by grinding a commercially available gradient lens. The bevel and the mirroring of the lens end face - as above explained - an image of the light-guiding fiber 3 on two descending fibers 4.5. The area ratio of the non-sanded to the sanded end surface determines the division ratio of the light stream 3a into the partial light streams 3a 'and 3a ". Therefore, this can be done very easily and in almost any size using appropriate Dimensioning the the ground surface can be adjusted, i.e. both symmetrical and strongly asymmetrical couplers can be produced.

In Fig. 2, a star coupler is shown, which is also after the principle described above has been created.

The 1/4 pitch long gradient lens 1 'is in its end area provided with two beveled mirror surfaces 7 ', 7 ", while the middle one Maintain the area of the end surface as the end surface 6 'parallel to the front surface 2'.

is.

Optical fibers 9, 10, 11, 12 are arranged on the lens front surface. The fiber 9 guides the light streams to be coupled in and divided into the partial light fluxes Luminous flux 9a.

This luminous flux is divided into the three partial luminous fluxes 9a ', 9a "and 9a"' split that after passing through the gradient lens on the front surface of the lens, namely., determined by the inclination of the mirror surfaces 7, 7 ', 7 ", at different points on the front surface of the lens. Here are the outgoing ones Optical fibers 10, 11, 12 arranged.

It should be mentioned that the course of the respective For the sake of clarity, light rays in the gradient lens are shown in a straight line became. The real course of the light rays is, according to the doping profile the gradient lens, but a parabolically curved -being, 4.h. as with gradient lenses known, the parallel entering luminous flux is expanded and deflected so, that the widened light stream also hits the end face in parallel again, The length of the lens is a whole number, uneven multiple (n) of 1/4 pitch length, where n can be 1, 3, 5 ..., but preferably = 1 selected will. After reflection on the end face, the expanded luminous flux is focused again and imaged on the front surface of the lens. The place of origin of this illustration is in the case of a conventional lens with parallel front and end faces of Coupling location dependent, i.e. how far the one coupling fiber from Center of the lens is set away.

The gradient lens is used to create a coupler with multiple outputs Sharpened facet-like, the number of facets determining the number of coupler ports As already mentioned above, these are the places of origin of the respective images of the coupling-in fiber on the face of the lens due to the inclination of the ground Area determined. With a fixed bevel angle, even in the case of van Star couplers fix all fibers in a suitable holder and in a single one Production step adjusted in front of the lens and in a conventional way, e.g. through Potting, to be fastened. The bevel and the mirroring of the lenses is also done preferably carried out in appropriate holders for several lenses at the same time.

In the above explanations it has been described that a in the Lens coupled luminous flux has been divided into two or more luminous fluxes, which are decoupled from corresponding optical fibers. However, it is the same it is quite possible to operate the respective coupler in the opposite direction, i.e. through the respective optical fibers 4, 5 or 10, 11, 12 luminous fluxes-in the gradient lens are coupled, which then becomes a single in the lens Luminous flux can be combined and coupled out through the fibers 3 and 9, respectively.

Claims (3)

Optical coupler Claims 1. Optical coupler for splitting of the luminous flux of an optical fiber in sub-streams or to combine sub-streams to a single luminous flux, characterized in that a Gradient lens (1, 1 ') from n. 1/4 pitch length is used, that one end the gradient lens in a partial area (7, 7 ', 7 ") at an angle (dJ to Lens end face (6, 6 ') is ground that the end provided with the bevel the gradient lens is mirrored, and that on the front surface (2, 2 ') of the gradient lens the incoming and outgoing optical fibers (3, 4, 5; 9, 10, 11, 12) in the imaging area the respective mirror surface are arranged. 2. Optical coupler according to claim 1, characterized in that the gradient lens with several, facet-like ordered bevel surfaces / mirror surfaces is provided. 3. A method for producing an optical coupler according to claim 1 or 2, characterized by the following process steps, a) several gradient lenses are inserted into a common holder, fed to a grinding device and be ground at the same time, b) the beveled lens ends are mirrored, c) the fibers to be arranged on the front surface of a respective lens are in Holders fixed and adjusted in front of the lens surfaces, and d) finally the fibers and the respective gradient pulses are inextricably linked.