DE3118582A1 - Optical coupler - Google Patents

Abstract

The invention relates to an optical coupler having a plurality of input gates and a plurality of output gates which can in each case receive radiation from each input gate. For this purpose, the optical coupler has an imaging arrangement, situated between the input and output gates and containing a phase grating, for transmitting the radiation emerging from the input gates to the output gates which are situated in the region of the radiation diffracted by the grating. The input gates are arranged in this case along at least one straight line at a spacing from one another such that the diffraction patterns of different diffraction orders of the ray fans assigned to the different input gates are superimposed on one another in the image plane. The output gates are arranged at least in the superimposition region of the diffraction patterns. <IMAGE>

Description

"Optical coupler"

The invention relates to an optical coupler, each with several entrance gates and several exit gates arranged along at least one straight line, as well as a phase grating with a 1 lying between the entrance and exit gates containing imaging arrangement for the transmission of the exiting from the entrance gates Radiation on that in an image plane and in the area of the diffracted by the grating Radiation exit gates.

A coupler of this type is already from the Japanese patent application No. 53-7684, published 8/8/1979.

It only has two entrance and two exit gates, the radiation can receive from any entrance gate. That in the pupil of the image arrangement lying phase grating is produced by means of an optical image, which generated by interference of the radiation emerging from the two entrance gates became. The phase grating therefore produces practically only two diffracted beams.

The object of the invention is to create an optical coupler, which compared to the known coupler also has a larger number of input and optical Output channels that can receive radiation from each of the input chambers, can own.

This object is achieved according to the invention in that the phase grating G is designed in such a way that there are fan beams with more than two diffracted beams generated that the entrance gates are arranged at such a distance from each other, that the diffraction patterns of different diffraction orders of the different Overlay entrance gates associated beam fan in the image plane, and that on Places where diffraction patterns are superimposed, exit gates are arranged.

Optical couplers of the type according to the invention, in which, if necessary, additionally also exit gates at locations of diffraction images generated by individual diffraction orders are arranged, a relatively large number of optical entrance and exit gates, which each lie on straight lines perpendicular to the grid furrows. Here you can if necessary, several output ports each radiation into a common optical output channel guide, so that radiation from each entrance gate can run through it.

According to an advantageous embodiment of the invention, the phase grating is of the optical coupler in such a way that there is a limited number v (according to the central, Diffraction orders of almost equal strength are generated in their intensity.

This ensures that the individual exit gates have an increased Catch the radiation component and the optical coupler has lower losses as a result. Grids of the type mentioned are, for example, from the article "Coherent optical generation ..." by H. Dammann and E. Klotz in Optica Acta, 1977, Vol. 24, No. 4, 505-515.

According to an advantageous development of the. Invention is the distance chosen between the entrance gates so large that the adjacent entrance gates are assigned Diffraction image groups by the distance between two neighboring diffraction images are offset.

If the number of diffraction orders generated by the grating is limited, with a distance chosen in this way between the entrance gates, that in the image plane a maximum number of superimpositions of different diffraction orders, the bundles of rays coming to different and from one entrance gate each belong, occurs. In this case, given the number of optical output channels the number of optical output gates can be reduced.

The drawing shows exemplary embodiments of the invention.

1 shows an optical coupler with three entrance ports, three Output ports and three optical output channels, and Fig. 2 shows an optical coupler with three entrance gates, five exit gates and three optical output channels.

The optical coupler shown in Fig. 1 has three, for example Entry gates 1, 2, 3 and three optical exit gates 4, 5 and 6 through which the Radiation in optical output channels 7, 8 and 9 passes through. The input and output gates are created by end faces or

End faces formed by optical fibers 10 (glass fibers).

Between the entrance and exit gates there is a binary, linear optical phase grating G, the grating grooves of which are perpendicular to the connecting straight lines the entrance and exit gates run. The phase grating G is Serncts VOII two Surrounding imaging lenses Li, L2, which provide an image of the exit ports 1, 2, 3 in cause an image plane E. The imaging lenses L1 and L2 and the beam path between the entrance and exit gates are only schematic here for the sake of clarity shown.

In order for radiation through an exit gate in each case in the associated optical output channel can be coupled from each entrance gate, must Grating G per entrance gate a fan of rays with a number of equal intensities Diffraction orders. generate at least the sum of the entrance gates and the exit gates, reduced by one, corresponds to. So if there are N entrance gates and M exit gates, so the grating must have at least a number of diffraction orders B = N + M-1 per fan produce. If the distances a between the entrance gates 1, 2 and 3 are chosen so, that the diffraction image groups B1, B2, B3 are offset from one another by the distance between two adjacent diffraction patterns, so the exit gates 4, 5 and 6 can be arranged so that they each receive radiation from all three entrance gates, as shown in Fig. 1 based on the symbols (full Triangles, squares, empty triangles). The number M of exit gates is correct here overlaps with the number K of the optical output channels. To () rtell to those If there is no radiation from all entrance gates, no exit gates are arranged. The corresponding radiation is lost.

Optical couplers of this type can largely be any number of entrance and exit gates or

Own output channels. A pair of numbers N, M can e.g. consist of two even or two odd numbers. Here, N can be greater than M or vice versa.

Fig. 2 also shows an optical coupler with N = 3 entry ports 11, 12, 13, which represent the ends of optical fibers (glass fibers), and with K = 3 optical output channels 14, 15 and iG. In order to emit radiation from To couple each entrance gate, a grid G is provided, the one per entrance gate Fan beams with a number of K = 3 diffraction orders (-1.0, + 1) are generated. the Distances a of the entrance gates are again chosen so that the through each a radiation fan generated diffraction image groups B'1, B'2, B'3 by the distance two adjacent diffraction patterns are offset from one another. In this way with three entrance gates 11, 12, 13, five resulting diffraction orders arise, whose radiation is to be intercepted through five exit gates 17-21.

The optical output channel 16 is here with its output gate 19 Arranged in the central diffraction order, the radiation from all three exit gates contains.

In contrast, the radiation in the output channels 14 and 15, respectively through two exit gates 17, 20 and 18, 21 collected in such a way that in the output channels 14, 15 radiation passes from each entrance gate. The exit gates 17, 20 and 18, 21 forming optical fibers 10 can be used to form the optical output channels 14, 15 each open into a common optical fiber, including a junction piece (so-called dB coupler) is used. The optical fibers to be combined in each case <let entrance gates 17, 20 or 18, 21 can be continued separately nucii and connected to a common receiver.

The optical coupler described in FIG. 2 can of course also be used equipped with a different number N of entrance gates or K of optical output channels be.

In general, if there is a number N of optical entrance gates and a number K of optical output channels the grating G per input port Fan of rays with a number of K diffraction orders must produce, where K is a is an odd number. Are they assigned to the individual entrance gates (n diffraction image groups offset from one another by the distance between two adjacent bedding images, so is equip the optical coupler with M = N + K-1 output ports 17 to 21. Here can N) K or vice versa. If necessary, more than two exit gates can become one optical output channel be summarized.

The optical couplers can also have two-dimensional arrangements of Have entrance and exit gates. For example, a coupler can have N = 9 entrance gates and K = 3 output channels from three of those shown in FIG. 1, one above the other in rows Orders exist.

The intercepted by the three exit gates in each column Radiation is then fed to an optical output channel in each case. Such two-dimensional Couplers can of course also be used with the arrangements described under FIG. 2 realize.

In the case of the two-dimensional couplers mentioned, the phase grating also be designed as a two-dimensional grid. For example, there are two linear phase gratings are provided, the grating grooves of which at an angle of e.g. 60 or rotated 90 ° against each other. Such two-dimensional lattice structures can be incorporated into a common glass or plastic carrier, e.g. by Etching or pressing.

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Claims (14)

PATENT CLAIMS: 1. Optical coupler, with several along each at least one straight line arranged entrance and several exit gates, and with a phase grating located between the entrance and exit gates Imaging arrangement for the transmission of the radiation emerging from the entrance gates on the radiation in an image plane and in the area of the radiation diffracted by the grating lying exit gates, characterized in that the phase grating (G) such is designed that there are beam fans with more than two diffracted beams generated that the entrance gates (1, 2, 3; II, 12, 13) at such a distance (a) are arranged from each other so that the diffraction patterns of different diffraction orders the fan beams assigned to the various entrance gates in the image plane (E) superimpose, and that in places where diffraction images are superimposed, exit gates (4, 5, 6; 19) are arranged. 2. Optical coupler according to claim 1, characterized in that in addition, exit gates nn locations generated by individual diffraction orders Diffraction images are arranged. 3. Optical coupler according to claim 1 or 2, characterized in that that individual and / or group-wise combined output gates with optical output channels (7-9; i4-16) are connected and arranged such that they are individually or in groups Collect diffraction images from all entrance gates (1-3; 11-13). 4. Optical coupler according to one or more of claims 1 to 3, characterized in that the phase grating (G) is designed such that There is a long allztthl of central, almost equally strong in their intensity Diffraction orders generated. 5. Optical coupler according to claim 4, characterized in that the distance (a) between the entrance gates is so large that the adjacent entrance gates assigned diffraction image groups (Bi, B2, B3) by the distance between two neighboring ones Diffraction patterns are offset from one another. 6. Optical coupler according to claim 1 and 3 to 5, characterized in that that the phase grating (G) with a number N of entrance gates (1, 2, 3) and one Number M of exit gates (4, 5, 6), each radiation from all entrance gates received, generated a fan beam with N + M-1 diffraction orders per entrance gate (Fig. 1), where N and M are pairwise even or odd numbers. 7. Optical coupler according to claim 6, characterized in that the number N of entrance gates (1, 2, 3) equals the number M of exit gates (4, 5, 6) is. 8. Optical coupler according to claim i to 5, characterized in that that the phase grating (G) at a number N of entrance gates (11,12, 13) and one Number K of optical output channels (14, 15, 16) per input Lor a beam fan generated with K diffraction orders, where the coupler M = N + K-1 output ports (17-21) (Fig. 2) and K is an odd number. 9. Optical coupler according to claim 8, characterized in that the number N of entrance gates (11, 12, i3) equal to the number K of optical output channels (14, 15, 16). 10. Optical coupler according to one or more of claims 1 to 9, characterized in that the input or. Fiber optic exit gates (10) are realized. 11. Optical coupler according to one o (ler several of claims 1 to 10, characterized in that in the case of exit gates to be combined in groups (17, 20 or 18, 21) an optical output channel (14 or 15) from several separate Consists of glass fibers. 12. Optical coupler according to one or more of claims i to 10, characterized in that in the case of exit gates to be combined in groups (i7, 20 or 18, 21) the respective glass fibers to form an optical output channel (14 or 15) open into a single glass fiber. 13. Optical coupler according to one or more of claims 1 to 12, characterized in that it has two-dimensional arrangements lying in one plane of entrance and exit gates. 14. Optical coupler according to claim 13, characterized in that the phase grating (G) is designed as a two-dimensional grating.