DE10007172A1 - Optical connector for optical communications system has reduced probability of faulty configuration by network management system - Google Patents

Abstract

The optical connector, which is connected between two optical cables (OL1, 0L2), each with an optical connection (OA1, OA2), also has an electrical connection for verifying the optical connection. The electrical connection is made or broken approximately simultaneously with the assistance of the optical connector. An electrical connecting cable (EVL) with connector elements (ESE1, ESE2) is laid with the optical connector and an electrical cable with counter connector elements (GSE1, GSE2) is laid with each optical conductor.

Description

The invention relates to an optical connector between two optical each having an optical connection Ladders and a method of loosening or plugging in optically Connectors.

In optical transmission systems, especially after WDM principle (Wavelength Division Multiplexing) working Transmission systems are used in optical network elements for example, optical coupling fields, manual optical connection switched through. For this purpose two op table connection, optical conductors via an opti cal connector connected to each other, the opti cal connector an optical connecting conductor and two each at the ends of the optical connecting conductor has attached optical plug elements. The optical Plug elements of the optical connecting conductor are in the optical connections of the optical conductors to be connected stuck and ultimately thereby an optical connection between rule a first optical conductor and a second opti ladder. In addition, the configuration the optical connector, d. H. each with an opti the connection assigned number of the optical plug connection connected first and second optical conductors, a network management system in the form of parameters posed. The existing configuration of the optical Plug connection can now be made with the help of the network management system present data visualized with a display unit become. If the network management system breaks the line of the first optical conductor is displayed due to the existing optical Ver binding of the first and second optical conductors through the  Network management system also on failure of the optical Connection closed.

However, an existing one can be entered manually Plug connection or the configuration of a network element displaying parameters in a database of the network management system stems errors occur, d. H. through the network management system a configuration of the Network element displayed. The probability of derar Incorrect configuration information is real in the past based transmission systems due to the complexity of WDM transmission systems - significant number of transmissions supply channels - very high, so that in the event of a incorrect configuration of a network element lization extremely complex and sometimes with one high economic effort is connected. To reduce the aforementioned probability of a manual, wrong Educational configuration is a means of providing optical channel for the transmission of configuration data to the network management system, the Reali Sation of such methods in optical transmission systems extremely cost-intensive and therefore economical Operation of optical transmission systems designed in this way is difficult to implement.

Furthermore, when manually inserting and removing an opti operator connection errors occur. This then leads to an incorrect forwarding of Si signals that are no longer evaluated at the recipient location can.

The object of the present invention is a Optical plug connection of the type mentioned at the beginning design that the likelihood of an error in the Network management system updated configuration reduced  becomes. Another object of the present invention is in this, the optical connector of the type mentioned above design that the likelihood of a faulty Plugging or unplugging an optical connector an operator is almost excluded.

According to the invention the object is achieved by an optical plug Connection of the type mentioned solved in the additional Lich an electrical connection to the optical connection provided for verification of the optical connector is. The additional electrical Ver binding the configuration of the optical connector indirectly when creating the optical connection the Netzma management system displayed, d. H. almost simultaneously with that Establishing the optical connection is already up to date ellsten. Configuration data for the network management system evaluation or evaluation. This will make it particularly special partial way the probability of a faulty ma Manual entry of the parameters of the existing connector configuration rations in the network management system avoided. So be through the optical transmission system itself the data for representation through the network management system Provided, with regard to the storage the economic data to be spent on configuration data wall is significantly reduced. Furthermore, it is advantageous way to configure one away from network management arranged system element allows. Prefers a locking mechanism is also provided, the the optical connector immediately after the first len locked or unlocked immediately before loosening to avoid a faulty connection. Particularly preferred the locking mechanism also locks all the plug connections that are free but not currently should be inserted. This prevents  a user can connect that not he wishes.

Advantageous further developments and training of the Invention according optical connector are in the claims Chen 2 to 10 described.

In a further advantageous embodiment of the above lying invention, the optical connector is flexible configured as an optical connecting line OVL1, OVL2. There by it is advantageously possible an optical Ver create a connection between any plug connections. The optical plug connection is particularly preferred as an op table connector designed OSV. This allows you to partly due to the given shape of the plug device tion OSV a connection between locally defined Optical connections are made, so that this further reduces the risk of faulty connections becomes.

It is particularly preferred in a further embodiment play a configuration signal KS to determine the configu ration state transferred. The transfer takes place of the configuration signal KS by means of transmission ei configuration signal. A means of transferring one digital configuration signal is particularly preferred electrical drain wire to the optical fiber. Especially be preferably as a means of transmitting a digital configuration tion signals are chip labels on both connectors of a ver Binding cable with inventory data that shows the togetherness of the two plugs to form a cable.

In a further preferred embodiment of the present The present invention is a control unit SE for evaluating the transmitted or not transmitted configuration signals  KS provided. The control unit SE evaluates them coming or not arriving configuration signals KS by capturing, storing and storing the signals processed. A center is preferred as the control unit SE ler network element calculator related.

A particularly advantageous embodiment has means for line concentration LK1, LK2 of the configurati on signals KS for several optical conductors OL1, OL2 can be connected by several connecting plug connections. Means for concentration LK1, LK2 are microprocessors or time multiplexers are particularly preferred. An arrangement of the proposed type is advantageous a manageability of the inlets and outlets as well as a ver reduced susceptibility to electromagnetic immissions and Emission.

In another particularly preferred embodiment a locking device VE is provided. With this ver locking device can preferably the opto-electrical An OEA are locked in such a way that an opto electrical connector OESE is not possible. Especially an opto- electrical plug element OESE when plugged in opto-electrical connection OEA be locked so that a No longer pulling the opto-electrical connector OESE is possible. The lock can, for example, by a radially narrowing circular element take place that into the circular recess A of the opto electrical connector OESE is inserted. Conceivable re also a sliding mechanism that is outside the opto- electrical connection OEA is attached to a socket B. or is placed inside the socket B in a recess. In the first case, the recess A would be the opto-electrical one OESE plug-in element is not necessary for the opto-electrical  Lock cable OEK. The locking process could be at for example, by an electric motor or a magnet be let.

In a further preferred embodiment, the Locking process by a central control unit SE controllable. This allows the specified planned plug connections are stored in the control unit and after are processed each other. All sockets or Ports of the plug connections are locked and only the Port to be unlocked, which will be plugged in next should. This allows the user to change a configuration protection from being protected even more effectively, connect to the wrong port. The be The already specified configuration can be in the control unit managed as a construction plan, processed step by step without the user inserting a connector incorrectly could - since the "wrong" ports are all locked.

A Ver to be solved but inserted is particularly preferred binding or a connection to be inserted and not yet inserted binding by an optical display, particularly preferably a Illuminated display LED, visualized. This makes it manual Operator easier to plug or unplug a connection tert, since it is now the connection to be disconnected or inserted can get displayed.

A preferred embodiment of a method according to the invention rens is that the locking device VE the to be released or inserted connection and that the locking device VE to be solved or to plugging connection after pulling or after plugging the Ver bond is closed. This enables Crossconnects CC can also be switched manually by untrained personnel,  and the error rate can increase with manual connection Lich be reduced.

A further preferred method form shows the one to be solved or connection to be plugged into the Crossconnect CC using a LED indicator light on. This becomes a problem to be solved or Visualize the interconnection on a Crossconnect CC made cash. This makes it considerably easier for the operator to recognize which connections on the Crossconnect CC are disconnected or should be interconnected.

The invention is intended to draw on the basis of several rical representations are explained in more detail. It shows:

Figure 1 shows the basic structure of an optical Steckvor direction with directly pluggable, electrical plug elements.

Figure 2 shows the basic structure of an optical Steckvor direction with an electrical circuit element.

Figure 3 is an optical connector system with electrical plug's rule, a control unit and an optical signaling.

Fig. 4 is a specific embodiment of an inventive SEN optical plug-in device in the released condition;

Fig. 5 was a specific embodiment of an inventive SEN optical plug-in device in the plugged to; and

Fig. 6 shows a basic structure of a cross-connect with optical patch panels (west, north, east, south).

In Fig. 1, an optical connector using an optical connector OSV and a holding plate HP having optical network element NE, for example, an optical coupling device is shown as an example. The optical plug-in device OSV has an optical connection conductor OVL, a first and second optical plug-in element OSE1, OSE2, and an electrical connection lead EVL and a first and second electrical plug-in element ESE1, ESE2, in FIG. 1 the optical plug-in device for example in the form has a semicircular ring, the ring ends of which are connected via a rectangular semicircular connection element HV. The optical connecting conductor OVL is arranged - centered in the semicircular ring - from the first optical plug element OSE1 to the second optical plug element OSE2, the first and second optical plug elements OSE1, OSE2 in a rectangular recess in the lower left and right corners of the rectangular semicircular connecting element HV are attached. In the remaining rectangular semicircular connecting element HV, the electrical connecting conductor EVL is guided, for example, in a semicircular arc or parallel to the optical connecting conductor OVL, the ends of the electrical connecting conductor EVL being attached to the first and the second electrical connecting element on the underside of the rectangular semicircle Plug-in element ESE1 / 2 are connected.

The connection-specific counterparts of the optical plug are connected to the holding plate HP of the network element NE arranged. On the top or the connection side of the Hal teplatte HP are for example a first and a second optical connection OA1 / 2 vertically on the holding plate HP ordered and fed from the bottom of the holding plate HP is the first optical conductor OL1 with the first optical Connection OA1 and the second optical conductor OL2 with the second optical connector OA2 is connected. Similarly are a first and second electrical mating connector GSE1 / 2 in the holding plate HP to hold the first and second electrical plug-in elements SE1 / 2 of the optical plug-in device  OSV arranged perpendicular to the holding plate, whereby a first to the first electrical mating connector GSE1 electrical conductor EL1 and to the second electrical counter plug element GSE2 a second electrical conductor EL2 guided are. The first and second electrical conductors EL1 / 2 are on a control unit arranged, for example, in the network element NE unit SE connected.

Is the optical connector using the example previously described optical plug-in device OSV in plug direction SR, so the first optical Steckele ment OSE1 with the first optical connection OA1 and that second optical plug-in element OSE2 with the second optical Connection OA2 connected and thereby the optical connection between the first optical conductor OL1 via the optical Connection conductor OVL and the second optical conductor OF2 closed. The first electri ESE1 plug element into the first electrical mating connector element GSE1 and the second electrical plug-in element ESE2 in the second electrical mating element GSE2 inserted. To in addition to the optical connector is an elek electrical connection via the first electrical conductor EL1, the electrical connector EVL the optical plug device OSV and the second electrical conductor EL2 ago via which a configuration signal KS from the control unit SE is transmitted to the control unit SE and in the control unit SE the presence of the configuration signal KS is evaluated. The evaluation of the configura tion signal KS in the control unit SE calculated information tion about the current configuration of the connector between the first and second optical conductors OF1 / 2, i.e. H. whether the optical connection is switched or not the network management system NMS in the form of parameters shows.  

A further embodiment of the plug connection according to the invention is shown in principle in FIG. 2, a single mechanical plug element ME being provided instead of the first and second electrical plug element ESE1 / 2 in contrast to FIG. 1. Similarly, the first and second electrical mating element GSE1 / 2 arranged on the underside of the holding plate HP and the electrical connecting conductor EVL connecting the first and second electrical element ESE1 / 2 are omitted. For this purpose, an electrical switching element ESE is seen in the network element NE in the holding plate HP that connects the first electrical conductor EL1 to the second electrical conductor EL2. In the holding plate HP, un directly above the switching point of the electrical Schaltelemen tes ESE, a recess is provided for receiving the mechanical plug element ME of the optical plug device. When the optical connection is plugged in, the mechanical switching element ME switches the electrical switching element ESE in the network element NE and thus, for example, establishes an electrical connection via the first electrical conductor EL1 and the second electrical conductor EL2, or in an alternative embodiment, for example, an electrical one Connection interrupted. In the case of an existing electrical connection, the configuration signal from the control unit SE via the first and two th electrical conductors EL1 / 2 to the control unit SE is transmitted analogously to FIG. 1, ie the concern of the configuration signal KS is evaluated in the control unit SE and the network management system NMS shows the optical connection in the form of parameters.

A further embodiment of the optical plug connection according to the invention is shown in FIG. 3 with the aid of an optical plug connection system which has a plurality of optical plug connections with flexible optical connecting conductors OVL and, in addition to the control unit SE, an optical signaling unit LSE. In Fig. 3 are a first, second, third, fourth, fifth and sixth opto-electrical connection OEA1, on the top of the holding plate HP. , ., OEA6 arranged, in addition to the respective opto-electrical connection OEA1,. , ., OEA6 preferably a light emitting diode LED1,. , ., LED6 is provided, ie there are a first, second, third, fourth, fifth and sixth light-emitting diode LED1,. , ., LED6 for displaying the operating state of the respective opto-electrical connection OEA1,. , ., OEA6 arranged on the top of the holding plate HP. Furthermore, in the network element NE, for example, a first and a second line concentrator LK1 / 2, an optical signaling unit or light-emitting diode control unit LSE and the control unit SE are provided, the first line technology concentrator LE1 via a first electrical conductor EL1 with the first opto-electrical Connection OEA1, via a third electrical conductor EL3 to the third opto-electrical connection OEA3 and via a fifth electrical conductor EL5 to the fifth opto-electrical connection OEA5. Analogously, the second line-technical concentrator LE2 is connected via a second electrical conductor EL2 to the second opto-electrical connection OEA2, via a fourth electrical conductor EL4 to the fourth opto-electrical connection OEA4 and via a sixth electrical conductor EL6 to the sixth opto-electrical connection OEA6 connected. In addition, the first line technology concentrator LE1 is connected to the control unit SE via the seventh electrical conductor EL7 and the second line technology concentrator LK2 via the eighth electrical conductor EL8. A ninth electrical conductor is guided from the control unit SE to the light-emitting diode control unit LSE, the first, second, third, fourth, fifth and sixth light-emitting diode LED1,. , ., LED6 is connected via an electrical control line ESL to the LED control unit LSE.

Analogously to FIG. 1 and FIG. 2, the opto-electrical connections OEA1,. , ., OEA6 optical conductor OL1,. , ., OL6, wherein, for example, the first optical conductor OL1 to the first opto-electrical connection OEA1, the second optical conductor OL2 to the second opto-electrical connection OEA2, the third optical conductor OL3 to the third opto-electrical connection OEA3 , the fourth optical conductor OL4 to the fourth opto-electrical connection OEA4, the fifth optical conductor OVLS to the fifth opto-electrical connection OEA5 and the sixth optical conductor to the sixth opto-electrical connection OEA6.

To make the optical connector are examples have a first and a second opto-electrical connection management manager OVL1 / 2 provided, each with an additional arranged parallel to the optical connection conductor OVL1 / 2 or integrated in the optical connection line OVL, first and second electrical connecting conductors EVL1 / 2 point. At the ends of the opto-electrical connection conductors OVL1 / 2 are opto-electrical plug-in elements OESE1,. . ., OESE4 for establishing the optical connector between, for example, the first and second opto-electri connection OA1 / 2 provided. In particular, the first one opto-electrical connection conductor OVL1 a first and a second opto-electrical plug-in element OESE1 / 2 and the second opto-electrical connection conductor OVL2 a third and four tes opto-electrical connector OESE3 / 4.

Should an optical connection between, for example, the third optical conductor OL3 and the fourth optical conductor OL4 are manufactured, then the third opto-electri The OESE3 plug-in element of the second opto-electrical connector cable conductor OVL2 on the third opto-electrical connection OEA3 and the fourth opto-electrical connector OESE4  the fourth opto-electrical connector OEA4. Consequently the optical connection is established. Almost simultaneously One of the first line concentrators becomes active LK1 from a main configuration received by the control unit ration signal by line deconcentration won nenes, second configuration signal KS2 over the third electrical conductor EL3, the third opto-electrical connection conclude OEA3, the second electrical connection conductor EVL2, the fourth opto-electrical connection OEA4 and the fourth electrical conductor EL4 to the second line Transfer concentrator LK2. In the second line technology Concentrator LK2 becomes the second configuration received signal KS2 together with, for example, a first, and third configuration signal KS1 / 3 to a main configuration on signal HKS concentrated in line technology and the conc main configuration signal HKS via the eighth elec electrical conductor EL8 transmitted to the control unit SE. In the control unit SE, the first, second and third Kon figuration signal KS1 / 2/3 evaluated and based on the the evaluation gained information the LED control LSE unit controlled. This in turn switches based on the control commands received from the control unit SE LEDs LED1,. . ., LED6 for example on or off or green or red. There are various circuitry for this Realizations possible, d. H. the visualization of the formwork Teten optical connectors is in no way on that Providing LEDs LED1,. . ., LED6 limited, but can also be achieved by other opto-acoustic display means gene.

Furthermore, in addition to the configuration signals KS1,. , ., KS6 obtained on / off information on the optical connections so-called "identifiers" for identifying the individual opto-electrical connections OEA1,. , ., OEA6 be transmitted with the aid of numbers assigned to the control unit SE, which the information - in particular the "identifier" - analogous to those in Figures 1 and 2 described arrangements back to the network Management system transmitted... The network management system is thus always informed of the latest configuration data directly from the optical transmission system, and this enables a current and reliable visualization of the configuration of the optical transmission system using the network management system. In the event of a fault, fault localization or troubleshooting can be carried out quickly and, above all, without considerable effort.

The illustrated by the embodiments in Fig. 1/2/3 inventive optical connector is not limited to the provision of only flexible optical Ver connection conductors or optical connectors, but it can also combinations of the functional properties explained in the examples, in particular the combination of flexible and "rigid" Verbindungslei tern, ie optical connectors, can be provided in a network element NE.

In FIG. 4 a specific embodiment is illustrated egg ner optical plug connection rule between an opto-electrical connecting cable OEK and a socket of a B Netzele ments NE in the released state by way of example. The opto-electrical connecting cable OEK has at one end an op-electrical plug element OESE consisting of a first optical connecting conductor OVL, a second optical connecting conductor wOVL, an electrical connecting conductor EVL, two test contacts ESK1, ESK2 and a receiving device A. . The socket B of the optical network element NE according to the invention has an opto-electrical connection OEA, a light indicator LED, a locking device VE, a first optical conductor OL, a second optical conductor wOL, two electrical conductors EL1, EL2, test contacts EAK1, EAK2, EAK3 and conductor L1-L3 for transmission of the configuration signals KS. The control unit SE is connected to a voltmeter SPM by a conductor L3. The voltage meter SPM is connected by an electrical conductor EL1 to the two test contacts EAK1, EAK2, a resistor R being attached between the test contacts EK1, EK2. In addition, the light indicator LED is connected by an electrical conductor EL2 via a switch SW to a voltage source SQ. The control unit SE is connected by the conductor L1 on the one hand to the switch SW, and on the other hand via the conductor L2 to a locking device VE.

Analogous to FIG. 4, FIG. 5 shows an optical plug connection between an opto-electrical connecting cable OEK and a socket B of a network element NE when plugged in. The opto-electrical plug element OESE of the connecting cable OEK is in socket B of the network element NE introduced in such a way that the test contact ESK1 is connected to the test contact EAK1 and the test contact ESK2 to the test contacts EAK2, EAK3. When plugged in, an optical connection is established between the first optical connecting conductor OVL and the first optical conductor OL and between the second optical connecting conductor wOVL and the second optical conductor wOL.

By way of example in Fig. 4 and Fig. 5 shown plug-in operation, an opto-electrical connecting cable is locked OEK of a network element in a bushing B. The locking unit VE is controlled via the central unit SE. The locking unit VE locks the opto-electrical connector OEA when the opto-electrical connector OESE is inserted, so that the opto-electrical connector OESE can no longer be released. The locking takes place by moving a locking device bolt VER from an open position into a closing position by the locking device bolt or the bolt of the sliding element VER is displaced into the recess A of the opto-electrical plug element OESE and thus locked.

For establishing or releasing an optical connector represents the embodiment of the invention a visual me mechanical security system available. By the central Control unit SE can the configuration state of the opti rule network element NE are determined and controlled. By the embodiment of the invention can also new faulty configuration states can be avoided.

If an inserted optical plug connection is to be released, the central control unit SE closes by means of an Si gnals over the conductor L1 the switch SW, this shows the Illuminated display LED indicates the optical connector to be disconnected, the central SE simultaneously sends a signal via the Lei ter L2 to the locking unit VE, which is in the socket B OESE plug-in opto-electrical connector unlocked. By now loosening the opto-electrical connector OESE will use the test contacts ESK1, ESK2, EAK1- EAK3 existing electrical line EL1, EL2 interrupted, the voltmeter SPM indicates a "zero level" and gives a configuration signal KS via the conductor L3 to the zen central control unit SE. The central control unit SE knows now that the correct optical connector has been disconnected, opens the switch SW by means of a signal from the conductor L1 again, whereby the light indicator LED is deactivated and causes the locking unit VE by means of the conductor L2 to lock the opto-electrical connection OEA.

The process of plugging the optical connector is analogous to releasing the optical connector. After the LED light indicates the correct socket B to be inserted, the opto-electrical connection OEA is unlocked at the same time. The opto-electrical plug element OESE can now be inserted into the opto-electrical connection OEA, the voltmeter SPM now shows a "level" where the central control element SE recognizes that the correct opto-electrical plug element OESE in the correct opto-electrical OEA connection was inserted. The central control element SE causes the locking device VE to lock the op-electrical plug element 4 ESE and to deactivate the light indicator LED.

Fig. 6 shows a basic structure of a cross-connect CC with optical patch panels. An exemplary application of the optical plug connections according to the invention is the manual interconnection of fields of an optical cross-connect CC by means of an opto-electrical connecting cable OEK. Patch panels (West, North, East, South) are provided as examples on an optical Crossconnect CC. The patch panels in turn have a linear sequence of sockets B on their side. A socket B1 from the West ST1 patch panel is connected to a B2 socket from the North ST2 patch panel. The connection is made by the opto-electrical connecting cable OEK that has an opto-electrical connector element OESE1, OESE2 at each end. The opto-electrical plug-in elements OESE1, OESE2 are connected to the opto-electrical connection OEA1 of socket B1 in the west patch panel and the opto-electrical connection OEA2 of socket B2 in the north patch panel.

To create or remove the correct optical connectors bindings on the optical patch panels must be the right ones optical plug connections and the plugging the wrong optical connections can be prevented.  

Should be on the optical patch panels of a Crossconnect CC an existing connection between two sockets B1, B2 of optical patch panels ST1, ST2 are solved, so that Central control unit SE, the circuit to be solved manually visible through LED indicators LED1, LED2 and unlocks the opto-electrical connections OEA1, OEA2 of the sockets B1, B2 by unlocking the locking device VE1, VE2. After pulling the first opto-electrical connector OESE1 the electrical line EL1 is connected via the test contacts ESK1, ESK2, EAK1-EAK3 interrupted, the voltmeter shows SPM a "zero level". The central control unit SE regi that the correct plug has been removed is deactivated the light indicator LED1 and locked by the locks VE1 the opto-electrical connection OEA1 as the so that it is protected from incorrect insertion. Analogous it is with the release of the second opto-electrical Plug element OESE2 on the second opto-electrical connection OEA2. The central control unit SE recognizes that the two correct optical connectors have been solved and goes back to the initial state. The central control unit is ready for new reconfiguration measures.

Should be on the optical patch panels of a Crossconnect CC two sockets B1, B2 are connected to each other, so do the central control unit SE to be connected manually Sockets B1, B2 of the optical patch panels by means of an illuminated display LED1, LED2 visible and unlock the opto-electrical on conclusions OEA1, OEA2 of the respective sockets B1, B2. By Plug the first opto-electrical connector OESE1 via the test contacts ESK1, ESK2, EAK1-EAK3 of the first op table connection made an electrical contact that Voltage meter SPM indicates a "single level", the central one Control element SE registers that the opto-electrical Stec kelement OESE1 was plugged into the OEA1 connection, locked applies the inserted optical connection through the locking device  VE1 against unwanted loosening and signali an intermediate state (e.g. by flashing). By plugging in the second opto-electr the OESE2 plug element in the opto-electrical connection OEA2 becomes an electrical contact via the test contacts ESK1, ESK2, EAK1-EAK3 and an optical connection poses. As a result, the voltage meter SPM shows a level between the "single level" and the "zero level" causes an electrical connection through a electrical connecting cable EVL in opto-electrical ver Binding cable OEK to the first optical connector stands and a voltage across the resistor R drops. The Central control unit LSE recognizes that the first op to-electrical plug-in element OESE1 with the second opto- electrical plug element OESE2 is connected, deactivated the indicator lights LED1, LED2 and locked by the ver Locking device VE2 the opto-electrical connection OEA2.

The invention thus provides an optical connector between two each have an optical connection (OA1, OA2) send optical conductors (OL1, OL2) ready, in addition an electrical connection to the optical connector provided for verification of the optical connector is. This will reduce the likelihood of being incorrect in the Network management system (NMS) detected, optical connector considerably reduced and the fault location within half of the optical transmission system facilitated.

Claims (14)

1. Optical connector between two optical connectors (OA1, OA2) each having optical conductors (OL1, OL2), characterized in that in addition to the optical connector, an electrical connection is provided for verification of the optical connector. 2. Optical connector according to claim 1, characterized, that the electrical connection is approximately simultaneously with Made using the optical connector or under will break. 3. Optical plug connection according to one of claims 1 or 2, characterized in
that with the optical plug connection, an electrical connecting conductor (EVL) with plug elements (ESE1, ESE2) is guided,
that with the optical conductor (OL1, OL2) each have an electrical conductor with mating connectors (GSE1, GSE2), and
that the electrical connection between the electrical conductors (EL1, EL2) is provided by the electrical connecting conductor (EVL) in the inserted state of the optical plug connection. 4. Optical plug connection according to one of claims 1 to 3, characterized in
that outside the optical connector, an electrical, through at least one plug element (ESE) switchable connection is performed, and
that the optical plug connection is designed such that in the switched state of the optical plug connection the at least one plug element (ESE) is actuated and the electrical connection is established or interrupted. 5. Optical plug connection according to one of claims 1 to 4, characterized, that means for transmitting a configuration signal (KS) are provided via the electrical connection, a transmitted or a not transmitted configuration signal (KS) indicates an optical connector. 6. Optical plug connection according to one of claims 1 to 5, characterized, that with one or more optical, two optical Conductors (OL1, OL2) connecting plug connections a tax unit (SE) for recording, storing and evaluating the transmitted or not transmitted configuration signals (KS) is provided. 7. Optical plug connection according to one of claims 5 or 6, characterized, that with several optical, two optical conductors each (OL1, OL2) connecting connectors means for line technical concentration (LK1, LK2) of the configuration signals (KS) are provided. 8. Optical plug connection according to one of claims 1 to 7, characterized, that the optical connection in a network element (NE) one optical transmission system is provided. 9. Optical plug connection according to claim 8, characterized, that in the optical network element (NE) and / or in network management system (NMS) using the electrical connection Configuration of the optical connector visualized becomes.   10. Optical connector according to one of the preceding Expectations, characterized, that a locking device (VE) is provided with the the optical plug element (OSE) and / or the electrical Plug element (ESE) in the opto-electrical connection (OA) and / or can be locked in the electrical connection (EA), in particular the opto-electrical plug element (OESE) in the opto-electrical connection (OEA) can be locked. 11. Optical plug connection according to claim 10, characterized, that the locking process by the control unit (SE) is controllable. 12. Optical connector according to one of the preceding Expectations, characterized, that the optical connector to be inserted and released through the optical connections (OA), the electri connections (EA) and / or the opto-electrical connections conclusions (OEA) corresponding light indicators (LED) vi are customizable. 13. A method for releasing or plugging an optical plug connection according to one of claims 1 to 12, characterized in
that the locking device (VE) of the connections to be loosened or inserted is opened, and
that the locking device (VE) of the connection to be detached or to be plugged in after pulling or plugging in the connection is closed. 14. Method of releasing or inserting an optical plug Connection according to one of claims 1 to 13, characterized, that to loosen and / or to plug in the optical connector the connections to be disconnected or inserted be shown.