DE3423221A1 - Optical star coupler having a large number of inputs and outputs - Google Patents

Abstract

The use of monomodal systems is imminent for optical communications. The distribution and exchange of information signals in the optical region can be carried out with the aid of a passive device, a so-called star coupler, by means of which it is possible to split channels from all incoming lines uniformly between all outgoing lines. The power division in the passive optical star coupler causes the main component of the attenuation between the large number of transmitters and receivers that are connected, and is thus decisive for the number of subscriber stations that can be connected. In embodiments of the invention, the attenuation based on the power division depends linearly on the maximum number of inputs or outputs. This is achieved by cascading coupler elements, e.g. 3 dB couplers, the coupler elements being connected to one another from one cascade stage to the other in such a way that it is not until downstream of the last cascade stage that each outgoing line has the same composition of the components of all the incoming signals. By way of example, including internal losses and attenuation on splices, in such a star coupler approx. 42 dB occur in Type 512.512, and approx. 14 dB in Type 8.8. <IMAGE>

Description

Optical star coupler with a large number

of inputs and outputs The invention relates to an optical star coupler with a large number of inputs and outputs.

For optical communications technology, the use of monomodal is characterized Systems. These allow due to the high transmission capacity in comparison to multimode systems and in particular to wire-based electrical systems Transmission and brokering the integration of further data and message services, in particular of broadband communication services.

Components for the construction of optical transmission links, d. H. mainly electro-optical converters, optical waveguides, especially fibers, and opto-electrical converters, are available and at the required quality Increasing demand undoubtedly also available at increasingly cheaper prices.

The aspirations also aim at the distribution and to carry out switching of communication signals in the optical domain, and in systems for a large number of connected subscriber stations. For such Point-to-point connections with flexible channel allocation should, if possible, in optical area largely z. B. on components and circuits for regeneration and amplifying the signals including back and forth conversion between optical and electrical areas can be dispensed with.

A passive device for the distribution and switching of optical Signals is a so-called star coupler, which allows signals to come from Distribute lines evenly on outgoing lines.

As a multiple power splitter, such a star coupler has a decisive influence the attenuation between a transmitter and a receiver of the system and thus the Size of the system, d. H. the number of transmitters and receivers that can be connected. For the following considerations under this aspect should initially cover all others Attenuation influences as well as the possibilities of this z. B. through intermediaries To compensate for amplifiers, to be neglected.

For single mode systems, directional couplers are used for distribution 1 to N known, see e.g. "Optics Letters" Vol. 8, No. 1, Jan. 1983, pages 60 to 62, and "Appl.Phys.

Lett. "40 (7), Apr. 1, 1982, pages 549/550. Thereafter, the same applies as without further understandable that within the technically achievable uniformity the radiated power is divided between the outputs with a factor of 1 / N. the Incidentally, the number of outputs N in these known directional couplers is in practice less than 10, e.g. B. maximum 7.

Type 1 distributors are of course sufficient for switching purposes x N alone is not enough. Imagine a straight-through star coupler of the type N x N from two mirror-image units of the type 1 x N emerged before, i.e. H. one inversely operated "divider" 1 x N as "collector" N x 1 on the input side and and yourself at the neutral point adjoining divider 1 x N on the output side, The factor 1 / N for the power sharing does not only apply to the output side, but rather for reasons of reciprocity also for the input side, d. H. total for one such a through star coupler 1 / N2.

Without taking into account any other damping influences as well Amplification possibilities would be a star coupler of the type according to these principles 100 x 100 already has an attenuation of -40 dB between the individual transmitters and receivers of the system. Under the conditions mentioned, this damping value may are not noticeably undercut in practice; the number of people in a messaging system Subscriber stations that can be connected with an optical star coupler would therefore be on less than 100 limited.

About an N x N single mode star directional coupler z. B.

in "Appl.Phys.Lett." 35 (2), July 15, 1979, pages 131-133. In the embodiments examined there with 4, 6, 8 and 10 alternately braided fibers could produce a remarkably good uniformity at the exits radiated power can be achieved. The effort required for a corresponding Structure with however orders of magnitude higher number of fibers, e.g. B. 100 or even 1000, however, should be too high, so that for this reason alone this known Solution for optical communication networks with a star structure and large numbers of subscribers seems unsuitable.

The star couplers known from multimode technology, at the fibers in greater numbers, e.g. B. up to 100, can be connected generally changes in cross-section, for example at the transition between fiber end faces and a glass rod face. Such cross-sectional changes are for monomode systems not suitable.

The invention is based on the object of showing a concept after the optical star coupler for a large number of channels with as few as possible Power division factor can be produced especially for single mode systems. According to the invention, this is achieved by a structure of cascaded coupler elements, of which the inputs of the first cascade stage are the inputs of the star coupler and the outputs of the last cascade stage form the outputs of the star coupler and the coupler elements of the cascade stages with one another by means of individual connections between the individual outputs of a cascade stage with one input each are regularly linked to another cascade level.

The solution according to the invention should be based on the assumption of ideal coupler elements to be explained in more detail: An ideal coupler element of the type 2 x 2 divides the radiated power from each of the two inputs in a ratio of 50:50, i.e. H. 3 dB on each of the two outputs. In a cascaded star coupler that contains such 3 dB elements in each cascade stage, applies to the power division from one transmitter to one receiver so the total of the dB values of the individual cascade levels. This corresponds to the theoretically possible optimum. The degree of coupling of incoming lines increases from cascade stage to cascade stage, d. H. after the last cascade stage, each outgoing line has the same complete line Composition of the components of the signals of all incoming lines.

As a star coupler, by the way, in this context not only such components / structures are understood where the number of inputs is equal to the number of outputs. A decrease in the number of coming or outgoing lines are easily possible by leaving them open or "blind". With regard to the division of services, however, nothing changes compared to the full wiring. Furthermore, it is also easily possible to connect to the outputs of a cascaded star coupler to connect 1 x N coupler and so on z. B. a large number of incoming lines to an even larger number of outgoing lines to distribute. With regard to the division of services based on the ideal 3 dB coupler elements in the individual cascade stages result with the next above-mentioned value of -40 dB for the system attenuation between a transmitter and a receiver that has 13 cascade stages with ideal coupler elements of type 2 x 2 can be provided in a single cascaded star coupler! That would be 213 = 8192 connections on the input and output side. Wise in practice 3 dB coupler, however, has a so-called insertion loss, i.e. internal losses in of the order of e.g. 1.5 dB to 2 dB. Then there are the losses the splice points at the connections between the coupler elements for which with 0.1 dB to 0.2 dB can be expected per splice. The number of Cascade stages with practically realizable 3 dB couplers, type 2 x 2, can then in cascaded star couplers according to the invention on a purely passive level about 8 to 9; d. H. such star couplers can - without intermediate or downstream connection of amplifiers - designed for 256 or even 512 inputs and outputs. is a higher system attenuation than -40 dB is acceptable, the dimensions of the cascaded Star coupler are multiplied accordingly.

In addition to coupler elements of the 2 x 2 type, there are also those of the Developed 3 x 3, 4 x 4, 5 x 5, etc.

These show the values accordingly with regard to the division of services 4.7 dB, 6 dB, 7 dB etc., but can be compared with regard to internal losses are better than previously available 3 dB couplers. The use of coupler elements different type leads in some cases to a cheaper solution, in particular when a star coupler is needed for a number of connections that are only slightly is greater than a power of 2, e.g. B. 300. 512 would be the next greater power of two. After the type of prime factorization, 300 can be written as the product 2 x 2 x 3 x 5 x 5 will. For the construction of a cascaded star coupler of the type 300 x 300 In other words, a cascading that can be completely wired with incoming and outgoing lines z. B. form elements of the type 2 x 2, 3 x 3 and 5 x 5. Otherwise would have to with a type 512 x 512 each 212 inputs and 212 outputs remain blind.

For preferred embodiments of the invention leaves themselves Mark the instructions for the general structure with one of the cascade levels s Coupler elements, each with n inputs and r outputs, and one next Cascade stage with r coupler elements, each with s inputs and m outputs. So-called original coupler elements have the size (n x r) or (s x m) or coupler elements of size (n x r) or (s x m) are used, which are each formed from an original coupler element of size (a x b), where for n, s - a and for r, m - b applies.

If e.g. due to a very high number of connections or off other reasons in embodiments of the invention the attenuation in a purely passive Star couplers should be too high, amplifiers, preferably optical amplifiers for the individual ege. These can be found on the incoming lines and / or the individual connections between the coupler elements of the cascade stages and / or on the outgoing lines. It is then possible to use the permissible System attenuation independent of division attenuation and internal losses of the coupler elements must be observed, i.e. the number of lines that can be connected in a system with a star network and optic channels freely to choose.

The solution according to the invention is primarily used for single mode systems optical star couplers with a large number of inputs and outputs are available to deliver. A few basic types, e.g. B. 2 x 2, 3 x 3, 4 x 4, 5 x 5 etc. can be used, each of which is required in large numbers are and are inexpensive as a mass product have made, e.g. as single-mode fiber couplers as well as monolithic single-mode waveguide couplers.

Polarization-maintaining components can also be used. The cascading of multimode fiber couplers is also possible for multimode systems advantageous and the structure also associated with fewer technical difficulties than with single mode components.

In the drawing are the principle underlying the invention and preferred embodiments of the invention shown schematically. Show: 1: a block diagram of a 3 dB coupler; Fig. 2: a block diagram of a cascaded star coupler, type 4 x 4, made up of 4 identical 3 dB couplers; 3: a coupler element, type 4 x 4, using a waveguide switching matrix; Fig. 4: a coupler element, type 2 x 2, using the waveguide switching matrix according to FIG. 3; 5: a block diagram of a coupler element type n x r with n = 4 and r = 2; Fig. 6: a block diagram of a coupler element type n x r, created of a type n x n, with r <n; 7: a block diagram of a coupler element Type n x r, developed from a type r x r, with n <r; Fig. 8: a block diagram of a coupler element type n x r, created from a type a x b, with n <a and r <b; 9: a complete block diagram of a Star coupler type 16 x 16; Fig. 10: a basic circuit diagram of a star coupler type 256 x 256; 11: a complete block diagram of a star coupler type 8 x 8; 12: a basic circuit diagram of a star coupler type 4 n x 4 n; Fig. 13: a block diagram of a star coupler type 2 n x 2 n; 14: a basic circuit diagram a star coupler type nm x mn; 15: a basic circuit diagram of a star coupler Type sn x mr; Fig. 16: a basic circuit diagram of a star coupler type 64 x 64 and FIG. 17: a section of the star coupler according to FIG. 16 for the simulation of the real ones Relationships with only 6 implemented channels.

The 3 dB coupler shown in Fig. 1 is known in the art U.N. commercially available passive optical components, both as four-port components can be manufactured with fibers as well as integrated waveguide components. It is essential for the embodiments of the invention that a uniform division and forwarding takes place from the incoming lines to the outgoing lines. Internal losses, for example insertion losses, of the order of magnitude from 1 dB to 2 dB, have an even effect. To the degree of evenness of the Power sharing between each of the two inputs and each of the two outputs no unusual requirements are made for embodiments of the invention. Since with such four-port the connections to each other and also the input and output side can be interchanged and the cascading a fixed connection of the individual Required coupler elements, there can be slight deviations to a certain extent the division ratios through targeted selection when connecting within the Compensate the cascade connection.

Fig. 2 shows a cascaded star coupler of the smallest size, the 4 x 4 type. It is made up of 4 coupler elements as shown in FIG. As below With the aid of the illustration in FIG. 1 it can be seen that - ideal coupler elements assumed without internal losses - half of one of the inputs to the both outputs of the relevant coupler element in the first cascade stage and from there to one coupler element each of the second cascade stage. Also takes place there a division of one of the inputs takes place in half on both outputs. At each of the 4 outputs, 1/4 of the power appears, which is via one the inputs of the star coupler is radiated.

This applies equally to all connections of the cascaded star coupler, d. H. it gradually merges from cascade stage to cascade stage more and more shares coming from the coming lines take place, up to behind the last cascade level the same at all outputs, proportions "Mixture" contained in all incoming lines appears. That is, from one Star coupler desired function, signals from all incoming to all outgoing Distributing lines evenly is fully met.

3 and 4 show coupler elements, each with a waveguide switching matrix according to the earlier application DE-P 33 44 490.0 (inventor: Heidrich / Hoffmann) can be used is. These switching matrices are intended for the construction of switching matrices and Contains a total of six individual waveguide switches offset in four stages. If the switching voltages are permanently set to specified values there, so the individual elements can function as a 3 dB coupler, an intersection switch, a parallel switch as well as in Fig. 4 by switching between the intersection and the parallel position of on / off switches. The circuit according to Fig. 3 then represents a star coupler or a coupler element of the 4 x 4 type, if switches 1/1, 1/2, 3/1 and 3/2 as a 3 dB coupler, switch 2 as an intersection and the switch 4 can be controlled as a parallel switch. As a coupler element of the type 2 x 2 is shown in FIG. B. only the switch 2 required, the is to be controlled as a 3 dB coupler. The respective upper and lower entrances and exits stay open, d. H.

unused. The switches 1/1 and 1/2 can be switched between crossing and Parallel position can be switched, the switches 3/1 and 3/2 as well as the itself Switch 4, which is not necessary in the present case, is firmly set to parallel position stay. In this way, functionally, a coupler element of the type is created 2 x 2 with input switches. With a corresponding swap the control conditions for switches 1/1, 1/2 and 3/1, 3/2 results in the Function of this element with output switches.

The previously mentioned coupler elements for embodiments of the invention are four-port elements or components composed of them that relate to the Power distribution between every two lines the factor 1/2 or the attenuation value Have 3 dB. However, the number of inputs and outputs need not be the same.

The function of a star coupler is also fulfilled when signals from a lower or higher number of incoming lines evenly to one higher or lower number of outgoing lines can be divided. In single mode systems this type of unbalanced star coupler can use components of type 1 x N in both Directions as well as with inherently symmetrical components are built up, in which some inputs and / or outputs remain unconnected, "blind".

Corresponding embodiments of the invention are shown in FIGS 8 shown.

The coupler element according to FIG. 5 of the type n x r with n = 4 and r = 2 corresponds in the internal structure to a composition of elements of the type 1 x x and y x y with x = 2 and y = 2. That still means that at each of the two outputs the level - assuming the ideal coupler - is one coming from one of the four inputs Signal is 6 dB lower. Of course, appear at each of the two Outputs the proportions of all four inputs.

For a coupler element according to FIG. 6 of type n x r, with n = 5 and r = 3, the factor 1/5 applies to the division of power, which corresponds to 7 dB.

Unfortunately, the power at the left open outputs remains unused A coupler element according to FIG. 7 of the type n x r with n = 4 and r = 7 arises from an element of the type r x r, in the present case 7 x 7, where for the power sharing 1/7 applies accordingly to 8.5 dB. Since some of the inputs remain blind, are at the outputs of course (but with -8.5 dB) only the proportions of the connected inputs to be found.

The most general case is shown in FIG. The type is n x r have been formed from a type a x b, where n <a and r <b, i.e. both some of the inputs and some of the outputs are left open.

Fig. 9 shows a cascaded star coupler of size 16 x 16, which consists of a total of eight elements according to FIG. 2, four each in two cascade stages, is constructed. The same applies to the internal structure of each of these eight coupler elements the rules for linking the elements of the two cascade stages accordingly, namely: each output of each element of the one cascade stage has one input each of each element of the veins cascade stage.

The individual connections between prefabricated elements can be of fiber ends with e.g. a splice at one point. Make such splices to an increase in attenuation of approx. 0.1 dB to 0.2 -dB, but this also applies to many Cascade stages are not added up to a noticeable attenuation component.

The transmission loss of the short fiber ends for the individual connections can also be changed of the elements can easily be neglected. The amount of work for splicing would be doubled if the fiber ends at the and inputs of the elements to be connected are not long enough and loose fiber ends must be used. The attenuation of this star coupler from Type 16 x 16 - ideally 12 dB - for a channel between a transmitter and a receiver, from the pitch loss, internal losses and the losses at the splice connections put together is about 4 x 3 dB + 4 x 1.5 dB + 3 x 0.2 dB = 18.6 dB.

In the cascaded star coupler according to FIG. 10, the coupler elements are Type 16 x 16, 16 pieces in each cascade level, in total in two cascade levels 32 pieces, of which only three are shown, connected together. The result is a star coupler of the type 256 x 256 with total attenuation - ideal 24 dB -of about 8 x 3 dB + 8 x 1.5 dB + 7 x 0.2 dB = 37.4 dB.

For a star coupler of the type 8 x 8 according to FIG. 11 are in two cascade stages a total of 12 coupler elements of the type 2 x 2 arranged. The two cascade levels are each shown as blocks drawn in dashed lines. The block of one The cascade level therefore contains four elements of the type 2 x 2, the block of the other cascade level 2 elements of the type 4 x 4, each in turn as an element according to FIG. 2 are constructed. This figure shows in particular that the structure of cascaded Star couplers according to the finding of unit elements that can have arisen from smaller unitary elements. It can also be seen that the first cascade stage also does this without further ado Star coupler of the type 8 x 8 the two unit elements of the type 4 x 4 and the second Cascade level which can contain four elements of the type 2 x 2.

The structure shown in Fig. 12 is based on this principle, in which unit elements of different types are cascaded. This star coupler is of type 4 n x 4 n and contains 4 n elements of type 2 x 2 and 4 elements of the Type n x n. The one cascade stage consists of two subunits, which are called those are also shown in FIG. Of these two coupler element blocks with Their 2n outputs lead the individual connections alternately from one and from the other block to the inputs of the 2n coupler elements of the type 2 x 2 the last cascade stage.

for the construction of a noppler Eletest of the type shown in FIG 2n x 2n, which is a block of n elements of the tip 2 x 2 and 2 elements of the type n x n exists, it can also be seen that this element is in one or the other Direction operated, at least in both possible orders of the two cascade stages can be built.

Fig. 14 shows an embodiment which is a basic formation rule for cascaded star couplers according to the invention. The one cascade level contains m elements of type n x n, the other n elements of the type m x m. The individual connections between the outputs of the elements of one cascade stage and the inputs of the elements of the other cascade level are to be carried out regularly in such a way that that every element of the one level reaches every element of the other level. If integer multiples of the n x m inputs or outputs are required, then such multiples are required Combine blocks in a corresponding number in a cascade level, their linking takes place through the individual connections with further cascade stages.

The embodiment shown in FIG. 15 is compared to that according to FIG represents a further generalization and is in connection with FIGS. 5 to 8 to see.

Then you need the individual coupler elements on the input and the output side does not necessarily have the same number of connected or have switchable connections. Such a cascaded star coupler results of type sn x rm, if elements are provided in one cascade stage which each have n inputs and r outputs, the other cascade stage r elements each element has s inputs and m outputs, and the r x s Individual connections between the s x r outputs and the r x s inputs of the respective Elements of the two cascade stages are produced regularly.

A cascaded star coupler of the 64 x 64 type is shown in FIG. 16 with the Coupler elements shown, which are necessary for understanding, d. H. several Elements and the individual connections belonging to them are for a better overview because of omitted. In one cascade stage there are 16 coupler elements of the type 4 x 4 provided (four are shown). The other cascade level contains four Coupler elements of the 16 x 16 type, each in blocks drawn with dashed lines presented represents, formed from eight coupler elements of the type 4 x 4 have been. All elements of the type 4 x 4 used here are in turn made from each four elements of the type 2 x 2 were created. The attenuation between a connected Transmitter and a connected receiver due to the power sharing (more ideal Coupler) is 6 x 3 dB = 18 dB.

FIG. 17 shows a section of the cascaded star coupler according to FIG Fig. 16 shows the twelve coupler elements of the type 2 x 2, which are used for simulation the complete arrangement with only six incoming and six outgoing lines are required, as are drawn as closed blocks. At a price of currently approx. 2,700 DM (1,000 US-ß) for a single-mode coupler element of the type 2 x 2 can thus be used for a demonstration model of a cascaded star coupler of the type 64 x 64 for coupler elements costs in the amount of approx. 486,000, - DM <180,000, - US- $) compared to the complete arrangement with a total of 192 coupler elements of the type 2 x 2 can be avoided.

Embodiments of the invention can e.g. B. in communication networks be used with optical channels, such as those from DE-OS 32 37 845 (inventor: Strebel, Bachus) or in the application DE - P 34 19 087.2 (inventor: Kreutzer, Heydt, Hermes) are revealed.

Claims (9)

Patent vEcohutz claims 9 optical star coupler with a large number of inputs and outputs, characterized by a structure of cascaded coupler elements, one of which the inputs of the first cascade stage, the inputs of the star coupler and the outputs of the last cascade stage form the outputs of the star coupler and the coupler elements the cascade levels with each other through individual connections between the individual Outputs of one cascade stage with one input of the other cascade stage are regularly linked. 2. Star coupler according to claim 1, characterized by one of the cascade stages with s coupler elements each having n inputs and r outputs, and one next Cascade stage with r coupler elements, each with s inputs and m outputs. 3. Star coupler according to claim 2, characterized by coupler elements the size (n x r) or (s x m). 4. Star coupler according to claim 2, characterized by coupler elements of size (n x r) or (s x m), each consisting of a coupler element of size (a x b) are formed, where for n, s - a and for r, m - b applies. 5. Star coupler according to one of claims 1 to 4, characterized by optical amplifiers in the individual ways. 6. Star coupler according to one of claims 1 to 5, characterized by Single mode fiber couplers as coupler elements. 7. Star coupler according to one of claims 1 to 6, characterized by monolithic single mode waveguide couplers as coupler elements. 8. star coupler according to claim 6 or 7, characterized by polarization-maintaining Coupler elements and lines for the internal and external connections Connections. 9. Star coupler according to one of claims 1 to 5, characterized by Multimode fiber couplers as coupler elements.