DE10041438B4 - Arrangement for coupling a plurality of first optical waveguide fibers with a plurality of second optical waveguide fibers - Google Patents

Abstract

Arrangement for coupling a plurality of first optical waveguide fibers (103) with a plurality of second optical waveguide fibers (113), - with a plurality of first optical waveguide connections (102) for optically coupling the first optical waveguide fibers (103), - with a plurality second optical waveguide connections (111) for optically coupling the second optical waveguide fibers (113), - with a plurality of coupling optical waveguides (108), each of which has a first coupling optical waveguide fiber (109) and a second coupling optical waveguide fiber ( 110) and can be coupled to one of the first optical waveguide connections (102) and one of the second optical waveguide connections (111), in each case one of the first optical waveguide fibers (103) via the first coupling optical waveguide fiber (109) can be coupled with one of the second optical waveguide fibers (113), - with at least one coupling detection unit (107, 104, 115, 116, 117, 118, 119), the one n optical transmitter (107), a third optical waveguide fiber (104), a fourth optical waveguide fiber (115), an optical receiver (116), an electrical contact (117), a first optical display unit (118) and a second optical Display unit (119) comprises, - in which the optical transmitter (107) via the third optical waveguide fiber (104) and one of the first optical waveguide connections (102) with the second coupling optical waveguide fiber (110) of one of the coupling optical waveguides (108) can be coupled, - in which the optical receiver (116) via the fourth optical waveguide fiber (115) and one of the second optical waveguide connections (111) with the second coupling optical waveguide fiber (110) of one of the coupling Optical waveguide (108) can be coupled, - wherein the optical receiver (116) is coupled to the first optical display unit (118) and the second optical display unit (119) via the electrical contact (117) in such a way that an electrical S. A signal for activating the first and second optical display unit (118, 119) is generated when the optical receiver (116) receives an optical signal which has been transmitted by the optical transmitter (107).

Description

The invention relates to an arrangement for coupling a plurality of first optical waveguide fibers with a plurality of second optical waveguide fibers.

In a plurality of optically coupled to each other at a coupling arrangement first optical fiber fibers with outgoing from the coupling arrangement second optical fiber fibers often occurs the problem to create a clear and relatively error-prone possibility of coupling the individual optical fibers. Furthermore, it is often desirable to automatically determine the information as to whether a coupling between two optical fibers is actually switched.

In this connection, it is known to use a clutch assembly having a plurality of first optical fiber connectors for optically coupling the first optical fiber and a plurality of second optical fiber connectors for optically coupling the second optical fiber. In each case one of the first optical waveguide connections is coupled to one of the second optical waveguide connections via a coupling optical waveguide.

The coupling arrangement is also referred to below as a maneuvering board or patch panel.

The coupling optical waveguide is also referred to below as a jumper connection or patch cord.

According to the known arrangement, the coupling optical waveguides are remotely connected via robotic arms to the incoming first optical waveguide fibers and the outgoing second optical waveguide fibers.

Furthermore, a coupling arrangement with optical switches is known.

Further, a clutch assembly is known in which the information transmitted over the fiber optic fibers in an optical channel is used to determine whether a transmission channel is switched, i. H. Whether two optical fiber fibers are mechanically coupled to each other and thus optically coupled together. In this coupling arrangement, an optical signal is directly coupled out of the optical channel for transmitting the useful information. This leads to an undesirable relatively high attenuation of the optical signal to be transmitted via the optical channel. Furthermore, the extraction of a signal from the optical channel, which is provided by the optical fiber, is very complicated and expensive.

The coupling arrangements known in glass fiber technology have the particular disadvantage that they are very expensive. Furthermore, it should be pointed out in this connection that, especially with optical waveguides, a change in the couplings between the individual optical waveguide fibers is rarely required. Taking into account this aspect, the known arrangements for use in glass fiber technology are oversized.

In the publication US 5,764,043 A An arrangement for interconnecting respective terminals of first and second distributors is described. The connections of the first distribution device can be coupled via a connecting cable with the terminals of the second distribution device. The respective connections of the two distribution devices have light-emitting diodes. The connection cables each include a pair of electric wires in addition to a signal transmission path for transmitting signals. In order to determine which connection of the first distribution device is coupled to which connection of the second distribution device via a connection cable, an external voltage supply unit can be connected to one of the connections of the first distribution device. When this terminal of the first distribution device is coupled to a terminal of the second distribution device via a connection cable, a closed circuit is formed by means of the electric wires of the connection cable between the power supply unit and the respective light emitting diodes of the terminals. The two light-emitting diodes indicate which connections are connected to each other in a plurality of connecting cables between the two distribution devices.

Thus, there is a substantial need for a clutch assembly which provides an operator of the clutch assembly, which manually couples the respective fiber optic fibers together, support for fast and secure detection and for fast and secure switching or

Provides coupling of the individual connections. In particular, it is desirable to avoid errors when disconnecting or connecting the transmission links, i. H. of clutches between two fiber optic fibers.

Thus, the invention is based on the problem of specifying an arrangement for coupling a plurality of first optical waveguide fibers with a plurality of second optical waveguide fibers, which is inexpensive and yet the coupling of Fiber optic fibers allows fast and error-resistant.

The problem is solved by an arrangement for coupling a plurality of first optical waveguide fibers with a plurality of second optical waveguide fibers having the features according to the independent claim.

Accordingly, an arrangement for coupling a plurality of first optical waveguide fibers to a plurality of second optical waveguide fibers comprises a plurality of first optical fiber ports for optically coupling the first optical fiber fibers and a plurality of second optical fiber ports for optically coupling the second optical fiber fibers. The assembly further includes a plurality of coupling optical fibers each comprising a first coupling fiber optic fiber and a second coupling fiber optic fiber and being connectable to a respective one of the first optical fiber connectors and one of the second optical fiber connectors, one each the first optical waveguide fibers can be coupled via the first coupling optical waveguide fiber to one of the second optical waveguide fibers. Furthermore, the arrangement has at least one coupling detection unit comprising an optical transmitter, a third optical fiber, a fourth optical fiber, an optical receiver, an electrical contact, a first optical display unit and a second optical display unit. The optical transmitter is coupled via the third optical fiber and one of the first fiber optic connections to the second coupling optical fiber of one of the coupling optical fibers. The optical receiver can be coupled via the fourth optical waveguide fiber and one of the second optical waveguide connections to the second coupling optical waveguide fiber of the one of the coupling optical waveguides. The optical receiver is coupled via the electrical contact with the first optical display unit and the second optical display unit such that an electrical signal for activating the first and second optical display units is generated when the optical receiver emits an optical signal emitted by the optical transmitter been received.

By means of the arrangement according to the invention, it is possible, without coupling out a signal from the optical signal, d. H. the optical channel, by providing a further channel, preferably a further optical channel or an electrical channel to determine whether two optical fiber ports are optically coupled to each other via a coupling optical fiber or not.

Thus, for example, it may be provided to couple or extract another optical signal in a frequency range into the optical waveguide fiber of the coupling optical waveguide, which differs from the frequency range in which the optical signal is guided by the incoming or outgoing optical waveguide fibers , In this case, the coupling optical waveguide likewise has one or more optical waveguide fibers, just like the incoming or outgoing optical waveguide fibers.

Alternatively, an additional fiber optic fiber may be provided in the coupling optical fiber. Via the additional optical waveguide fiber, a further optical signal is fed by means of an optical transmitter, which is in each case preferably assigned to a first optical waveguide connection. An optical signal transmitted by an optical transmitter is received by a respective optical receiver assigned to a second optical waveguide connection if the two respective optical waveguide connections are connected to one another via the coupling optical waveguide. In this case, a coupling information is thus transmitted via a further optical waveguide fiber in the coupling optical waveguide, by means of which indirectly, i. H. Without being able to intervene in the optical signal circuit between the incoming and outgoing optical waveguide fibers, it can be determined whether a connection is connected between two optical waveguide connections.

According to a further embodiment of the invention, an additional electrical line, preferably made of copper, is provided in the coupling optical waveguide.

Via the additional electrical line in the coupling optical waveguide, an electrical signal is fed by means of a voltage or current source, which is preferably assigned in each case to a first optical waveguide connection and coupled thereto via an electrical contact provided in the optical waveguide connection. A respective electrical contact provided by the voltage source or current source is received via a further electrical contact, which is preferably arranged in a second optical waveguide connection, when the two respective optical waveguide connections are connected to one another via the coupling optical waveguide. In this case, a coupling information is thus transmitted via an additional electrical line in the coupling optical waveguide, by means of which it can likewise be indirectly determined whether a connection is connected between two optical waveguide connections.

Indirect determination in this context is to be understood in such a way that it is inferred from this additional information of the further channel (optical or electrical) that the corresponding optical coupling is present or not.

The invention makes it possible for the first time to determine in a simple and cost-effective manner whether optical waveguide fibers are coupled to a patch panel and to one another via a patch cord without having to intervene in the actual optical signal circulation.

Thus, in the solution according to the invention, the optical signal to be transmitted via the incoming or outgoing optical waveguide fibers is not attenuated.

According to one embodiment of the invention, a plurality of coupling detection units is provided, wherein in each case a coupling detection unit is assigned to a first optical waveguide connection and / or a second optical waveguide connection.

This refinement allows a simple and thus cost-effective assignment of the detected couplings to the respective optical waveguide connections.

According to a further embodiment of the invention, an optical coupler is provided on at least a part of the first optical waveguide ports for coupling a further optical signal into the optical channel of the optical waveguide fibers. Further, an optical decoupler is provided on at least a part of the second optical waveguide terminals for coupling out the optical signal from the optical channel of the optical waveguide fibers.

This embodiment provides a simple and thus cost-effective implementation possibility of an additional optical signal circuit for detecting the corresponding optical couplings, wherein not even an additional electrical line or an additional optical fiber in the coupling optical waveguide is required.

Furthermore, for at least a part of the first optical waveguide connections and for at least a part of the second optical waveguide connections, in each case an electrical connection can be provided, to which an electrical line additionally provided in the coupling optical waveguide fiber can couple electrically, if the coupling Fiber optic fiber is coupled to the corresponding optical waveguide connection, According to a further embodiment of the invention, a central processing unit is provided, preferably a microprocessor, with which processing unit all couplings between a first optical fiber connection and a second optical fiber connection via a respective coupling Fiber optic fiber can be captured and stored.

By means of the central processing unit can also be specified, which optical fiber connections are to be coupled to each other via a coupling optical fiber.

In this way, reliable complex automated detection, processing and storage of the optical couplings can be realized even with complex coupling structures of a high number of coupled optical waveguide fibers. Furthermore, an overview of the respective optical fiber connections already connected can be provided in this way centrally.

Furthermore, an optical display unit can be provided for at least part of the first optical waveguide connections and for at least part of the second optical waveguide connections, which optical display unit is coupled to the central processing unit such that an optical display unit is activated if the respective optical waveguide Connector coupled to an optical fiber.

The optical display units can be controlled by the central processing unit, for example by means of different color specifications, in order to assist the fitter in the interconnection of the coupling optical waveguides by correspondingly lighting the optical display units of the optical waveguide connections to be interconnected.

In this way it can be displayed cost-effectively and very clearly for a fitter, which clutches have already been switched and thus, which clutches are actually to be switched by the installer.

In accordance with a further embodiment of the invention, the optical display units or further optical display units can furthermore be provided to indicate to the fitter which first optical waveguide connections are to be coupled with which second optical waveguide connections.

In this way, the assembly itself is made clearer for the fitter and thus easier and mistakerobuster designed.

Furthermore, it can alternatively be provided that the first optical waveguide connections are each assigned a button as a switch and the second optical waveguide connections are each assigned an optical display unit, so that when a button is pressed in the event that the corresponding first optical waveguide connection via a coupling Optical waveguide is coupled to a second optical waveguide port, the corresponding, the respective second optical fiber port associated optical display unit is activated, so that a user at the touch of a button each receives the light information about which second optical fiber connection of the respective first optical fiber connection is coupled.

The switch can be realized as a key or as an open contact, in which the electrical contact is formed by contact with a finger and thus the switch is conductively closed. Furthermore, the key can be designed as a one-contact button.

Embodiments of the invention are illustrated in the figures and are explained in more detail below.

Show it

1 a cross-sectional view of a coupling arrangement with a coupling optical waveguide according to a first embodiment of the invention;

2 a cross-sectional view of a coupling arrangement not according to the invention with a coupling optical waveguide; and

3 a plan view of a clutch assembly according to the first embodiment of the invention.

3 shows an incoming fiber optic cable 300 , via which a plurality of optical signals having a multiplicity of different center wavelengths λ ₁ , λ ₂ ,..., λ _n as a total signal 301 one with the fiber optic cable 300 coupled wavelength multiplexer / wavelength demultiplexer 302 , according to this embodiment, an AWG Wavelength Division Multiplexer / Wavelength Demultiplexer (Arrayed Waveguide Grating Wavelength Demultiplexer) 302 can be supplied.

In the AWG Wavelength Division Multiplexer / Wavelength Demultiplexer 302 becomes the total signal 301 into the multitude of optical signals 303 with the center wavelengths λ ₁ , λ ₂ , ..., λ _n divided. Every optical signal 303 each becomes a first fiber optic fiber 304 via a transponder 305 fed.

Every first fiber optic fiber 304 each with a first fiber optic connection 306 a clutch assembly 313 coupled, which will be explained in more detail below.

The coupling arrangement 313 also has one of the number of first optical fiber connections 306 corresponding number of second optical fiber connections 307 on.

At a second fiber optic connection 307 can each be a second fiber optic fiber 308 be coupled.

One with a first fiber optic connection 306 coupled first fiber optic fiber 304 can, as in 3 shown by means of a coupling optical waveguide via a correspondingly selected second optical fiber connection 307 with one with the respective second optical fiber connection 307 coupled second fiber optic fiber 308 coupled and thus optically coupled.

The second fiber optic fibers 308 be via another transponder 309 another AWG wavelength division multiplexer / wavelength demultiplexer 310 supplied in which the optical signals 303 corresponding to another overall signal 311 be multiplexed. The overall signal 311 becomes another outgoing fiber optic cable 312 fed.

Of course, the arrangement can also be operated in the reverse signal flow direction, in which case the functionality of the AWG wavelength multiplexer / wavelength demultiplexer is configured correspondingly reversed.

1 shows a cross section through the clutch assembly 100 , The coupling arrangement 100 has a front panel 101 on with a received in a bore first optical fiber connector 102 which is formed by an MT-RJ connector, generally a two-fiber connector for connecting a plurality of optical fibers 103 . 104 ,

A first fiber optic fiber 103 , which at a first connection part 105 with the first fiber optic connection 102 is coupled, is one on the clutch assembly 100 incoming fiber optic fiber. About the first fiber optic fiber 103 an optical useful signal is transmitted to the actual user data transmission.

About a second fiber optic fiber 104 , which at a second connection part 106 with the first fiber optic connection 102 is coupled, an additional optical signal from an optical transmitter 107 , the first fiber optic connector 102 is assigned to the first optical fiber connection 102 guided.

As in 1 shown is the first fiber optic connection 102 also on its other connection side with a coupling optical fiber 108 coupled.

The coupling fiber optic cable 108 has a first coupling optical fiber 109 and a second coupling optical fiber 110 on.

The first coupling fiber optic fiber 109 is with the first fiber optic fiber 103 optically coupled, so that the optical useful signal from the first optical fiber 103 the first coupling fiber optic fiber 109 is supplied.

The second coupling optical fiber 110 is with the second fiber optic fiber 104 optically coupled, so that by an optical transmitter 107 generated further optical signal from the second fiber optic fiber 104 the second coupling fiber optic fiber 110 is supplied. The optical transmitter 107 is a light emitting diode or a laser.

The other end of the coupling fiber optic cable 108 is with a second fiber optic connection 111 coupled, in a further bore of the clutch assembly 100 is arranged, which second optical fiber connection 111 also formed by a MT-RJ two-fiber connector.

About a first connection part 112 of the second optical fiber connector 111 is the first coupling optical fiber 109 with one of the clutch assembly 100 outgoing, third fiber optic fiber 113 optically coupled, thereby providing optical signal transmission from the first fiber optic fiber 103 over the first coupling optical fiber 109 of the coupling optical waveguide 108 to the third fiber optic fiber 113 is possible.

Via a second connection part 114 of the second optical fiber connector 111 is the second coupling optical fiber 110 with a fourth fiber optic fiber 115 coupled. The fourth fiber optic fiber 114 in turn is with an optical receiver 116 coupled.

Thus, an additional, according to this first embodiment, optical, signal circuit of the optical transmitter 107 over the second fiber optic fiber 104 , the second coupling optical fiber 110 and the fourth fiber optic fiber 115 to the optical receiver 116 created.

By means of this additional signal circulation can now be signaled whether the first optical fiber connection 102 with the corresponding second optical fiber connector 111 is coupled.

The optical receiver 116 is according to this embodiment with an electrical contact 117 and above with a first light emitting diode 118 and a second light emitting diode 119 coupled as optical display units.

Receives the optical receiver 116 an optical signal, an electrical signal is generated and by means of the electrical signal, the two LEDs 118 . 119 activated. Further, the electrical contact 117 with a computer 120 as a central processing unit via an electrical line 121 connected as a control and detection line.

By means of the computer 120 according to this embodiment, with all the electrical contacts of the second optical fiber connections of the coupling arrangement 100 is coupled, on the one hand, all existing optical couplings between each a first optical fiber connection 102 and a second optical fiber connector 111 be queried and on the other hand, the light-emitting diodes 118 . 119 be driven and activated, even if the corresponding optical fiber connections are not yet coupled together to indicate to a user, which optical fiber connections are to be coupled together and / or coupled together.

According to an alternative embodiment, it is provided that the electrical contact 117 with a computer 120 as a central processing unit via an electrical line 121 is connected as a control and detection line and not directly with the light-emitting diodes 118 . 119 , In this case, the light emitting diodes 118 . 119 only centrally from the computer 120 activated, ie activated or deactivated.

In other words, this means that from the computer 120 the light-emitting diodes 118 . 119 the first and second optical fiber connections to be coupled together are activated to optically indicate to the fitter Fiber optic connections are to be coupled together. If the optical fiber connections are coupled together, this will be done by the computer 120 recorded and the corresponding LEDs 118 . 119 are disabled again, so that the fitter is visually displayed that the coupling is switched error-free.

According to this embodiment, two separate signal circuits are thus illustratively formed, one for detecting the coupling information and one for driving the LEDs 118 . 119 ,

The computer 120 is also equipped with a data display device 122 coupled to display desired information to a user.

In this regard, it should be noted that instead of an MT-RJ connector, an SCDC connector or other multi-fiber connector may alternatively be used.

2 shows a cross section through a non-inventive coupling arrangement 200 ,

The coupling arrangement 200 has a front panel 201 on with a received in a bore first optical fiber connector 202 which is formed by a first connector, which first optical fiber connector 202 with an electrical contact 203 is provided.

A first fiber optic fiber 204 , which with the first fiber optic connection 202 is coupled, is one on the clutch assembly 200 incoming fiber optic fiber. About the first fiber optic fiber 204 an optical useful signal is transmitted to the actual user data transmission.

About the electrical contact 203 gets an extra electrical signal from a battery 205 or any other power source as the power source, to the first fiber optic port 202 via a first electrical line 209 from a computer 215 to the first fiber optic connector 202 guided.

The electrical contact 203 of the first optical fiber connector 202 is formed by a conductor of a circuit board.

The first fiber optic connection 202 is designed electrically conductive.

As in 2 shown is the first fiber optic connection 202 also on its other connection side with a coupling optical fiber 206 coupled.

The coupling fiber optic cable 206 has a coupling fiber optic fiber 207 as well as an electrical line 208 made of a copper stranded wire that connects Kevlar together around the coupling fiber optic fiber 207 is laid.

The coupling fiber optic fiber 207 is with the first fiber optic fiber 204 optically coupled, so that the optical useful signal from the first optical fiber 204 the coupling fiber optic fiber 207 is supplied.

The electrical line 208 of the coupling optical waveguide 206 is with the electrical contact 203 of the first optical fiber connector 202 electrically coupled, so that of the battery 205 provided electric power from the battery 205 over the electrical line 209 the electric wire 208 of the coupling optical waveguide 206 is supplied.

The other end of the coupling fiber optic cable 206 is with a second fiber optic connection 210 coupled, which is also formed by an electrically conductive connector.

Via the second fiber optic connection 210 is the coupling fiber optic fiber 207 with one of the clutch assembly 200 outgoing, second optical fiber 211 optically coupled, thereby providing optical signal transmission from the first fiber optic fiber 204 via the coupling fiber optic fiber 207 of the coupling optical waveguide 206 to the second fiber optic fiber 211 is possible.

The second fiber optic connection 210 is also with an electrical contact 212 Mistake. The electrical contact 212 of the second optical fiber connector 210 is also formed by a conductor of a circuit board.

In this regard, it should be noted that between the front panel 201 and the respective electrically conductive components of each first optical fiber connector 202 and every other optical fiber connection 210 each an insulating body 213 is provided as an electrically insulating element, so that a short-circuit current between the electrically conductive components of the optical fiber connections 210 over the front panel 201 is avoided.

In general, an electrical insulation of the electrically conductive components of the optical fiber connections 202 . 204 and the coupling points with respect to the optical waveguide components and the front panel 201 provided to avoid a short-circuit current.

The electrical contact 212 of the second optical fiber connector 210 is via a second electrical line 214 with the computer 215 connected such that a closed electrical circuit is formed when the first optical fiber connection 202 over the coupling optical fiber 206 with the second fiber optic connection 210 is coupled.

Thus, there is an additional signal circuit from the battery 205 over the first electrical line 209 , the electric wire 208 of the coupling optical waveguide 206 and the second electrical line 214 to the computer 215 created. By means of this additional signal circulation can now be signaled whether the first optical fiber connection 202 with the corresponding second optical fiber connector 210 is coupled.

The computer 215 is via a third electrical line 216 as a control and detection line with a further electrical contact 217 and above with a first light emitting diode 218 and a second light emitting diode 219 coupled.

Receives the computer 215 an electrical signal via the second electrical line 214 so will from the computer 215 generates an electrical control signal and by means of the electrical control signal, the two LEDs 218 . 219 activated or deactivated.

By means of the computer 215 that with all the electrical contacts of the first fiber optic connections 202 and the second optical fiber connectors 210 the clutch assembly 200 is coupled, on the one hand, all existing optical couplings between each a first optical fiber connection 202 and a second optical fiber connector 210 be queried and on the other hand, the light-emitting diodes 218 . 219 be driven and activated, even if the corresponding optical fiber connections are not yet coupled together to indicate to a user, which optical fiber connections are to be coupled together.

The computer 215 is also equipped with a data display device 220 coupled to display desired information to a user.

In the following, some alternatives to the above arrangements are shown.

There may be different types of wiring for electrical contacting in the optical fiber connections 202 . 210 be provided.

Thus, the electrical connection, in particular the electrical contacts in the optical fiber connections can be configured by means of multilayer printed circuit boards as a matrix. In this way it becomes possible to achieve a simple connection topology even with high packing density.

Furthermore, other types of wiring, such. B. form cable of individual wires or metal rails that receive the optical fiber connections can be provided.

Furthermore, the electrical line 208 the coupling optical fiber 206 are formed from a network of electrically conductive elements in analogy to a coaxial cable.

Furthermore, the electrical line 208 the coupling optical fiber 206 are formed from an aluminum sheath or a strip-shaped electrical wire made of aluminum.

It should be noted in this context that the clutch assembly may be modular. In this case, a conventional connector module is provided with the elements described above. Each module includes a predetermined number of first optical fiber connectors and second optical fiber connectors, preferably 12 first optical fiber connectors and 12 second optical fiber connectors.

The modules are picked up by a rack. The individual fiber-optic connections are coupled to the central processing unit via a bus.

Due to the modularity of the coupling arrangement, it is possible to flexibly expand a distribution point from a few optical waveguide fibers to a very large number of optical waveguide fibers.

Claims (8)

Arrangement for coupling a plurality of first optical waveguide fibers ( 103 ) with a plurality of second optical fibers ( 113 ), - with a plurality of first optical waveguide connections ( 102 ) for optically coupling the first optical waveguide fibers ( 103 ), - with a plurality of second optical fiber connections ( 111 ) for optically coupling the second optical fibers ( 113 ), - with several coupling optical waveguides ( 108 ), each having a first coupling optical fiber ( 109 ) and a second coupling optical fiber ( 110 ) and each having one of the first optical fiber connections ( 102 ) and one of the second optical fiber connections ( 111 ) can be coupled, wherein in each case one of the first optical waveguide fibers ( 103 ) over the first coupling fiber optic fiber ( 109 ) each having one of the second optical waveguide fibers ( 113 ), - with at least one coupling recognition unit ( 107 . 104 . 115 . 116 . 117 . 118 . 119 ), which has an optical transmitter ( 107 ), a third fiber optic fiber ( 104 ), a fourth fiber optic fiber ( 115 ), an optical receiver ( 116 ), an electrical contact ( 117 ), a first optical display unit ( 118 ) and a second optical display unit ( 119 ), - in which the optical transmitter ( 107 ) over the third fiber optic fiber ( 104 ) and one of the first optical fiber connections ( 102 ) with the second coupling optical fiber ( 110 ) one of the coupling optical fibers ( 108 ), - in which the optical receiver ( 116 ) over the fourth fiber optic fiber ( 115 ) and one of the second optical fiber connections ( 111 ) with the second coupling optical fiber ( 110 ) of the one of the coupling optical waveguides ( 108 ) is coupled, - wherein the optical receiver ( 116 ) via the electrical contact ( 117 ) with the first optical display unit ( 118 ) and the second optical display unit ( 119 ) is coupled such that an electrical signal for activating the first and second optical display unit ( 118 . 119 ) is generated when the optical receiver ( 116 ) an optical signal transmitted by the optical transmitter ( 107 ) has been sent. Arrangement according to claim 1, With a plurality of coupling recognition units, - In each case one coupling detection unit is assigned to one of the first optical waveguide connections and / or one of the second optical waveguide connections. Arrangement according to one of Claims 1 or 2, having a central processing unit ( 120 ), with which a coupling between the one of the first optical waveguide connections ( 102 ) and one of the second optical fiber connections ( 111 ) via the second coupling optical fiber ( 110 ) and stored, the central processing unit ( 120 ) via an electrical line ( 121 ) as a control and detection line with the electrical contact ( 117 ) connected is. Arrangement according to Claim 3, in which the central processing unit ( 120 ) is designed as a computer. Arrangement according to claim 4, wherein by means of the computer an existing optical coupling between the one of the first optical waveguide connections ( 102 ) and one of the second optical fiber connections ( 111 ) is queriable. Arrangement according to Claim 5, in which the first and second optical display units ( 118 . 119 ) are controlled such that the first and second optical display unit ( 118 . 119 ) are activated when one of the first fiber optic connections ( 102 ) with one of the second optical fiber connections ( 111 ) is to be coupled. Arrangement according to one of Claims 1 to 6, in which the first optical waveguide connections ( 102 ) in each case a switch is assigned, - in each case one of the second optical display units ( 119 ) each one of the second optical fiber connections ( 111 ), wherein upon activation of the respectively assigned switch of one of the first optical waveguide connections ( 102 ) each one of the second optical display units ( 119 ) of one of the second optical waveguide connections ( 111 ) is activated when one of the first fiber optic connections ( 102 ), whose switch has been actuated, with one of the second optical waveguide connections ( 111 ) is coupled. Arrangement according to one of claims 1 to 7, wherein the first and second optical display unit ( 118 . 119 ) are each formed as light-emitting diodes.

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