FR2680067A1 - Method of monitoring a line distributor; auxiliary cable, connector and distributor for implementing this method - Google Patents

Abstract

The present invention relates to a method of managing line distributors with an auxiliary cable, as well as novel line distributors, connectors and auxiliary cables for implementing this method. By virtue of the presence, on each auxiliary cable 14 linking two fixed connectors 3, 5 of a line distributor, of a linking means 16 for identification of the connection formed by the cable, which is provided in addition to a linking means 15 between two lines 8, 10 connected to the said fixed connectors, a control means 20 can draw up the list of connections formed in the line distributor. The invention also allows simple and rapid identification of a chosen connector, by virtue of optical signalling means 32.

Description

METHOD FOR CONTROLLING A LINE DISTRIBUTOR;
AUXILIARY CABLE, CONNECTOR AND DISTRIBUTOR
FOR THE IMPLEMENTATION OF THIS PROCESS
The subject of the present invention is a method of controlling a line distributor, and an auxiliary cable for connecting two fixed connectors of a line distributor, said cable comprising a means of connection between two lines connected to said fixed connectors and comprising, at each of its ends, a movable connector capable of being paired with one of said fixed connectors. It also relates to the line distributors using them and to the connectors to which they will be connected.

 The invention applies inter alia in the field of telecommunications and cable television networks, in particular in the line distributors of such networks.

However, it can be applied in all kinds of industries requiring the linking, in a repetitive and / or progressive manner, of a large number of links such as metallic wires, optical fibers or channels of the same type.

 The problem which the invention proposes to solve is that of monitoring and managing the auxiliary cables on the line distributors and, in particular, the invention makes it possible to make the installation of the auxiliary cables less sensitive to human errors.

 A network, and in particular a telecommunications network, such as a telephone network, can be modeled by nodes, linked together by links. The nodes can be terminal nodes, such as, for example, subscribers of a telephone network. The nodes can also be nodes internal to the network, such as for example the automatic exchanges of a telephone network.

Such a network generally comprises links of two types. On the one hand, there are distribution links.

A distribution link is a link which terminates at a terminal node of the network. For example, for a telephone network, this is a link between a subscriber and the local branch exchange; it can for example comprise a single line physically constituted by a "telephone pair", that is to say by a pair of metallic cables. There are also transport links. A transport link is a link which connects two internal nodes to the network, that is to say for example two automatic exchanges of a telephone network. In such a network, a transport link often comprises several lines and can be physically carried out by a metal cable with several conductors, or by a bundle of optical fibers. We will consider below that a link consists of one or more lines. It may, for example, be optical fibers, in the case of broadband multiservice telecommunications networks.

 From an economic perspective, it is interesting to optimize the size of the physical links installed, in order to make the best use of them given their capacity; however, all traffic on the network must be ensured.

 It is also important to be able to vary the topography of the network to adapt it to the needs and resources available. As a result, the physical links are often made up of sections, of possibly different capacity, the end-to-end connection of which constitutes the link. It is then necessary to ensure the connection between the ends of the sections which meet.

 In order to be able to optimize the use of the physical resources of the network, it is important to provide for cross-connection means, that is to say to make possible changes in the connections of the lines constituting the links. It is interesting that the possible modifications do not relate to the physical links, but take place in the communication nodes.

 A line distributor is a device that performs this dual function of connection and patching. Generally, it thus comprises a first set of connectors, upstream side, and a second set of connectors, downstream side. Each of these sets of connectors forms a so-called strip. Each connector of each strip can be connected on the one hand to a line of a connection. On the other hand, each connector of a strip can be connected to another connector of the other strip. This last connection is ensured by an internal auxiliary cable to the distributor, called a jumper. Thus, the distributor of the type described below makes it possible to ensure the connection between the upstream connection lines and the downstream connection lines, by means of a series of jumpers. It also makes it possible to ensure mixing between the lines of the upstream links and the lines of the downstream links, by modifying the positions of the jumpers in the distributor, without physically intervening on the upstream and downstream links.

 Such a distributor can be placed between distribution links and a PABX. In this case, different distribution links, corresponding for example to different subscriber lines, are connected on the upstream side to the first strip. On the downstream side, the various inputs of the PABX are connected to the connectors of the second strip. Auxiliary cables or jumpers connect one by one the connectors of the first strip to the connectors of the second strip, and allow the different lines of the subscribers to be connected to the different inputs of the PABX. The use of jumpers allows a quick and easy modification of the connections between the subscriber lines and the PABX inputs.

 An important problem which makes it possible to solve the invention is that encountered by the operators of telecommunications networks, of the management of distributors, and more precisely of the installation and the monitoring of the garters of distributors. The connection of the various garters is often modified, for example for the introduction of new subscribers on the network, or for new line assignments. The installation of garters, which is done manually, is a tedious and repetitive operation, in which the operator can very easily make a mistake. During a shuffle, that is to say when changing the connection of different jumpers, the operator can also very easily make a mistake, without his error can not be easily identified. Finally, it is important to periodically check the status of the connections of a distributor, and to establish a list, or to check the list, which is a long and tedious operation.

 There are many devices to control the wiring of telephone distributors, but they do not solve all the problems posed by the management of distributors: In particular, they cannot be used for lines of different nature, for example for lines made up of optical fibers and lines made up of metallic conductors. In addition, they do not allow both monitoring of the distributors and assistance with the installation of auxiliary cables or jumpers.

 The present invention relates to a method of controlling a line distributor, to identify a connection made by an auxiliary cable between two fixed connectors of said line distributor, consisting in establishing between these two fixed connectors, in addition to the connection between two lines connected to these two fixed connectors, a connection identification link made by the cable.

 According to an embodiment of the method according to the invention, it further comprises an optical signaling allowing the identification of the fixed connectors.

 According to another embodiment of the method according to the invention, in order to identify two fixed connectors which must be connected by an auxiliary cable to establish a given connection, it also consists in transmitting two optical signals respectively near these two connectors fixed.

 According to yet another embodiment of the method according to the invention, in order to identify two fixed connectors connected by an auxiliary cable which must be moved or removed, it also consists in transmitting two optical signals respectively near these two connectors fixed.

 According to yet another embodiment of the method according to the invention, in order to identify a fixed connector, it also consists in transmitting an optical signal near this fixed connector.

 The present invention further relates to an auxiliary cable of the aforementioned type comprising a second connecting means for identifying the connection made by the cable.

 According to one embodiment of the cable of the invention, the connecting means between two lines connected to said fixed connectors is an optical fiber.

 According to another embodiment of the cable of the invention, the second connection means for identifying the connection is a metallic conductor.

 According to one embodiment of the invention, the fixed connectors each further comprise optical signaling means allowing their own identification, said optical signaling means consisting for example of a light-emitting diode.

 The invention further relates to a line distributor comprising two strips of fixed connectors and auxiliary cables intended to connect two by two of the fixed connectors of each of the strips, which auxiliary cables are of the aforementioned type.

 According to one embodiment of the invention, the line distributor further comprises control means, means for transmitting and receiving a signal, for transmitting and receiving a signal between two fixed connectors connected by a cable auxiliary, and distributor and selector means, for choosing said fixed connectors.

 According to another embodiment of the invention, the line distributor further comprises signal transmission means for transmitting a signal to the optical signaling means of a fixed connector, and distributor means for choosing said fixed connector .

 The present invention transforms the positioning of the garters into a simple and easily achievable operation, and virtually eliminates any possibility of operator error; it also allows monitoring of the connections set up, which can be carried out on site after an intervention, or remotely. Thanks to the present invention, it is possible to obtain a state of the connections in the distributor, quickly and simply.

 The present invention can be implemented on distributors of all types. It can be applied to metallic distributors; in a preferred embodiment, it applies to optical distributors, that is to say distributors ensuring the connection between optical fibers.

 The present invention is here described with reference to the example of line distributors of telecommunications networks and, more particularly, optical distributors. It is obvious that it can be implemented on any type of system of the same kind, for example in connection systems of multiplicity of parallel lines. Another example of a possible field of use of the invention is the cable television network, or any similar network.

The characteristics and advantages of the present invention will emerge more clearly from the following description, given solely by way of nonlimiting example, relative to an optical distributor, and with reference to the appended drawings, where:
- Figure 1 shows a block diagram of a
first embodiment of the device
according to the invention, intended for supervi
connection control;
- Figure 2 shows a block diagram of a
second embodiment of the device
according to the invention, intended to help in
in addition to the placement of garters.

 FIG. 1 represents a block diagram of a first embodiment of the device according to the invention. This embodiment of the invention is described with reference to the example of a fiber optic distributor, which in the following description is designated an optical distributor. FIG. 1 therefore represents an optical distributor 1, comprising a first set or strip 2 of fixed connectors 3. The distributor 1 comprises a second set or strip 4 of fixed connectors 5; the fixed connectors 3, 5 are multiple connectors, which each comprise a first fixed connection means 6 and a second fixed connection means 7. The first fixed connection means 6 of a connector 3 or 5 has two inputs and allows ensuring the optical connection of two optical fibers placed on these two inputs. Similarly, the second fixed connection means 7 of a connector 3 or 5 has two inputs, and makes it possible to provide the electrical connection of two electrical conductors connected to these two inputs. One will designate thereafter, by the expression "upstream connector", one of the fixed multiple connectors 3 of the first strip and, by the expression "downstream connector", one of the fixed multiple connectors 5 of the second strip 4. It is understood that these expressions have no meaning other than the descriptive meaning assigned as well.

 Each of the upstream connectors 3 can be connected by the first input of its first fixed connection means 6 to an optical fiber 8 of a link 9. In the example of FIG. 1, there is shown such a link 9 and fibers optics 8 connected to upstream connectors. Each of the downstream connectors 5 can be connected by the first input of its first fixed connection means 6 to an optical fiber 10 of a link 11. Conventionally, there is, on each of the optical fibers 8, 10, a loop 12, 13 allowing a later modification of the connections. For reasons of clarity, we have limited ourselves to representing in FIG. 1 a limited number of upstream 3 and downstream 5 connectors and a limited number of optical fibers 8, 10 and links 9, 11.

 Each of the upstream connectors 3 can be connected to any one of the downstream connectors 5, by means of a jumper 14. There is also shown, for reasons of clarity, a single jumper 14 connecting two upstream and downstream 3 connectors 5. This jumper 14 comprises an optical fiber 15 and a metallic conductor 16. It comprises, at one of its ends, a movable multiple connector 17 and, at the other end, a movable multiple connector 18. The movable multiple connector 17 can be connected to an upstream connector 3 so that the corresponding end of the optical fiber 15 is optically connected to the second input of the first connection means 6 of the upstream connector 3, and that the corresponding end of the metal conductor 16 is electrically connected at the second input of the second connection means 7 of the upstream connector 3. The movable multiple connector 17 is connected to an upstream connector 3 so that it can be easily detached or hung up. For example, the mobile connector 17 can be in the form of a plug which can be plugged into an upstream connector 3. The mobile multiple connector 18 disposed at the other end of the jumper 14 can, similarly, be connected to a connector downstream 5, so as to connect the corresponding ends of the optical fiber 15 and the metal conductor 16 respectively to the second input of the connection means 6 of the downstream connector 5 and to the second input of the connection means 7 of the downstream connector 5. Thus , the jumper 14, which connects two upstream 3 and downstream 5 conductors, makes it possible to establish an optical connection between the two fibers 8 and 10 connected respectively to the first input of the first connection means 6 of the upstream connector 3 and to the first input of the first connection means 6 of the downstream connector 5. The jumper 14 also makes it possible to establish an electrical contact, via the conductor 16, between the second inputs of the second means connection ens 7 of the upstream 3 and downstream 5 connectors. In this way, using a multiplicity of such garters 14, an operator can connect any of the upstream connectors to any of the downstream connectors, and the different connections thus formed can be easily modified by moving the garters.

 The principle of the jumper connection between the upstream and downstream connectors of a distributor for optical fibers according to the invention has been described above. The supervision device according to the invention will now be described. It comprises a control apparatus 20 which includes input means, display means, means for storing input data and results, and control means. The control device 20 is connected to a control link system 21. The control device 20 can, for example, consist of a microcomputer or a microprocessor system, and the link connection system command then consists of a bus. The device according to the invention further comprises a signal transmitter 22, a signal receiver 23, a first addressing means 24 and a second addressing means 25 which are all connected to the control link system 21, and which are controlled by the control device 20, through the control link system 21.

The device according to the invention further comprises a distributor 26 and a selector 27. The distributor 26 is connected to the signal transmitter 22, to the first addressing means 24 and to the first input of the second connection means 7 of each upstream connectors. Similarly, the selector 27 is connected to the signal receiver 23, to the second addressing means 25 and to the first input of the second connection means 7 of each of the downstream connectors.

 On command from the control device 20, the signal transmitter sends a signal to the distributor 26. In this first embodiment, this signal is an electrical signal. The distributor 26 routes this signal to the first input of the second connection means 7 of a chosen upstream connector. This upstream connector is chosen by the control device 20, and the choice is transmitted to the distributor 26 via the control link system 21 and the first addressing means 24. The choice is made for example from a list reference numbers assigned to the upstream connectors. In this way, an electrical signal is sent by the signal transmitter to the second connection means of a chosen upstream connector. On the side of the second strip 4 of multiple fixed connectors, the selector 26 connects the second connection means 7 of a downstream connector 5 to the signal receiver 23. This downstream connector is chosen by the control device 20, and the choice is transmitted to the selector 27 via the command link system 21 and the second addressing means 24. The choice is made, for example, from a list of reference numbers assigned to the downstream connectors. Thus, the signal receiver can receive an electrical signal present on the second connection means 7 of a downstream connector chosen by the control device 20.

 The mode of operation of the device according to the invention is described below. It makes it possible to supervise the optical distributor; this can consist in checking the connection of a certain number of jumpers from data when their theoretical connection. The device according to the invention also makes it possible to obtain a list of all the connections made by jumpers in the optical distributor.

 To check whether two upstream 3 and downstream 5 connectors of the first and second strips 2 and 4 of fixed connectors are connected by a jumper 14, the control device 20 transmits by the data link system 21 to the first means d addressing 24 the reference number of the chosen upstream connector. It also transmits by the data link system 21 to the second addressing means 25 the reference number of the chosen downstream connector. Once the first and second addressing means 24 and 25 have received these reference numbers, the control means 20 activates the signal transmitter 22 and the signal receiver 23. The signal transmitter transmits an electrical signal to the distributor 26. The distributor 26 routes the electrical signal to the upstream multiple connector whose reference number is supplied to it by the first addressing means, that is to say to the upstream connector chosen by the control device 20. The electrical signal emitted thus arrives at the second connection means 7 of the chosen upstream connector. If a jumper 14 is connected by its movable multiple connector 17 to the chosen upstream connector, the electrical signal passes through the metallic conductor 16 of this jumper, and arrives at the second connection means 7 of the downstream connector to which the other end of the garter. Two cases are then possible. If the jumper 14 is in the position provided, the downstream connector on which the electrical signal arrives is that of which the number has been transmitted by the control device 20 to the second addressing means 25. The selector 27 then transmits the signal electrical signal signal 23, and the control means 20 can then see that the transmitted signal has been received. Thus, if a jumper 14 is placed between the multiple upstream and downstream connectors chosen, the signal emitted by the signal transmitter 22 is received by the signal receiver 23, and the control device 20 checks the presence of the jumper. Otherwise, if no jumper is arranged between the upstream and downstream connectors chosen, the signal receiver 23 does not receive the signal emitted by the signal transmitter 22, and the control device 20 can deduce therefrom absence of garter. In this way, it is possible to check whether a jumper is placed between two chosen upstream and downstream connectors.

 The device according to the invention also makes it possible to obtain a list of all the connections made by jumpers between the upstream and downstream connectors of the distributor.

For this, the control means successively searches, for each upstream connector, if this upstream connector is connected to a downstream connector by a jumper. This is done by browsing the list of downstream connectors for each upstream connector. Each test on the presence of a jumper between two given connectors takes place as described above. Thus, a state of the connections is quickly obtained in the automatic switch, which is carried out without human intervention and which eliminates the tedious and repetitive work of manual verification by an operator of the position of the jumpers.

 FIG. 2 represents an embodiment of the invention which also makes possible easy installation of the garters of an optical distributor 1 and which facilitates the task of an operator by reducing the probability of human errors during the placement of garters. We are talking about implementation here. Obviously, the invention also applies when it comes to moving or removing garters. The elements represented in FIG. 2 and similar to those of FIG. 1 are identified by identical reference numbers.

 As before, the optical distributor comprises a first strip 2 of fixed multiple connectors 30, and a second strip 4 of fixed multiple connectors 31. They will be called new upstream connectors 30 and downstream connectors 31. The upstream and downstream connectors are identical to those described with reference to Figure 1, except that they further comprise an optical signaling means 32; this means can be constituted by any optical source, or by a mobile mechanical device making it possible to locate a given connector. By way of example, in the embodiment described here, light-emitting diodes are used as a means of optical signaling. These diodes have two terminals in known manner and light up in the presence of a suitable current between these two terminals. Each connector of one of the two connector strips therefore comprises two connection means 6 and 7 as well as a light-emitting diode 32. The connections of the upstream and downstream connections, as well as the connections of a device similar to that described with reference to FIG. 1 can be carried out as described above, and they are therefore not shown in FIG. 2.

 The control means 20 is connected via the control link system 21 to an upstream signal transmitter 33, to an upstream addressing means 35, to a downstream signal transmitter 34, and to a downstream addressing means 36. The device according to the invention further comprises an upstream distributor 37, as well as a downstream distributor 38. The upstream distributor 37 is connected to the upstream signal transmitter 33, and to the upstream addressing means 35, as well as to the first terminal of the light-emitting diode 32 of each of the upstream connectors 30. The light-emitting diode 32 of each upstream connector 30 is, moreover, connected by its second terminal to a feedback circuit, constituted by a metallic conductor connecting said second terminals between them and to the upstream signal transmitter 33. In the context of this embodiment, a light-emitting diode 32 has been considered as an optical signaling means. This diode lights up under the effect of an electric current. Consequently, the upstream signal transmitter 33 is capable here of transmitting an appropriate electrical signal. The upstream distributor 37 is capable of routing an electrical signal emitted by the upstream signal transmitter 33 to the light-emitting diode 32 of one of the connectors 30. The upstream distributor 37 routes the electrical signal to the light-emitting diode of the connector 30 which is chosen by the control means 20, for example by a number in a list. This choice is transmitted via the control link system by upstream addressing 35, and this in turn transmits it to the upstream distributor 37.

An electrical signal emitted by the signal transmitter 33 is therefore routed to the light-emitting diode of one of the upstream connectors 30, passes through this diode causing the emission of a light signal and returns by the return circuit to the upstream signal transmitter. In this way, the control means 20 can choose an upstream connector, transmit this choice by means of upstream addressing, then activate the upstream signal transmitter. The latter then emits an electrical signal which passes through the upstream distributor, is routed to the light-emitting diode of the chosen connector, and returns to the signal transmitter by the return circuit. Thus, the light emitting diode of the chosen upstream connector emits an optical signal, which allows an operator to quickly identify the chosen connector.

 The connections on the downstream side of the distributor between the downstream distributor, the downstream signal transmitter, the downstream addressing means and the light-emitting diodes of the downstream connectors are the same as the connections on the upstream side between the upstream distributor, the transmitter upstream signal, the upstream addressing means and the light emitting diodes of the upstream connectors. The operation of the device on the downstream side is the same as on the upstream side, and the control means 20 can also choose a downstream connector and cause the light-emitting diode of this connector to transmit an optical signal.

Thus, an operator can quickly identify the chosen downstream connector.

 Thanks to the device according to the invention described with reference to Figure 2, the installation of garters is greatly facilitated. Thus, for the installation of a jumper between a given upstream and downstream connector, the control means 20 can cause a light signal to be emitted on the upstream connector, which indicates to the operator where to connect the first movable connector 17 d 'a jumper 14. Next, the control means 20 can cause a light signal to be emitted on the downstream connector, which indicates to the operator where to connect the second movable connector 18 of the jumper 14.

 The operator can have a predetermined time to make the connection, before having to make the next connection. Alternatively, the control means 20 can wait for the operator to enter a validation command before proceeding to the next operation. In this case, the operator has more time for difficult connections, and should not wait for connections that he can make quickly. To change the position of a jumper, the control means can firstly send an optical signal of a first type, to signify to the operator that he must remove the movable multiple connector from the connector whose diode emits this first signal. I1 can then transmit an optical signal of a second type, so as to indicate to the operator where to connect the multiple connector. For example, the first signal can be a continuous light signal and this second signal an intermittent light signal. It is clear that the examples above, but can be used to help operators in all interventions on the garters of a distributor.

 Two embodiments of the present invention have been described below with reference to FIG. 1 and to FIG. 2. In its first embodiment, the invention provides a device for monitoring a distributor. In its second embodiment, it also provides a device for assisting in the installation of garters, using optical signaling means.

 The present invention has been described in a preferred embodiment, where the jumper 14 is composed of an optical fiber 15 and a metallic conductor 16. This corresponds to the choice of electrical devices for the signal transmitter 22 and for the signal receiver 23. The distributor 26 and the selector 27 are then composed of multiplexers and demultiplexers of known type. The first addressing means 24 and the second addressing means 25 can then consist of buffers produced for example from flip-flops of known type.

 Of course, the invention could also have been described in the embodiment where the jumper 14 is made up of two optical fibers. In this case, the signal transmitter 22 and the signal receiver 23 are opto-electronic devices. They are controlled by the control link system 21 and are optically connected respectively to the distributor 26 and to the selector 27. The distributor 26 and the selector 27 are, in this case, optical switches with electrical control, optically connected to the second means of connection 7 of multiple fixed connectors.

 The device according to the invention can be produced so as to constitute a portable device, easily adaptable to different distributors. Thus, in FIG. 1, the optical distributor designated by the reference numeral 1 comprises the two connector strips, the distributor 26 and the selector 27. The signal transmitter 22, the signal receiver 23, the addressing means 24 and 25 are detachably connected to the distributor 1, and constitute with the control means 20 and the control link system 21 a portable assembly. An operator having to check the state of the connections in a distributor can record the theo risk state of the connections in the storage means of the control means 20, then then connect the portable assembly to the distributor, and record the actual state of the connections. In this way, the portable assembly can be used for different distributors.

 In FIG. 2, the distributor 1 comprises the two strips of fixed multiple connectors. The upstream signal transmitter 33, the downstream signal transmitter 34, the upstream distributors 37 and downstream 38 are detachably connected to the distributor 1 and constitute, with the upstream 35 and downstream addressing means 36, the control system 20 and the control link system 31, a portable assembly. In this way, only the connectors remain permanently in the distributor, and the other elements of the device can be used for various distributors.

 The device according to the invention can also be a fixed device. For example, for a large distributor, on which interventions are frequent, it may be more profitable than all of the elements described with reference to Figures 1 and 2 always remain in place.

 It is also possible to provide a data link between the control means 20 and a control center, which allows remote monitoring of the optical distributor. Alternatively, the control means 20 can be arranged remotely.

 The control means 20 has not been described in detail.

It can take any suitable form and include various types of capture or storage devices. It can contain a multiplicity of programs intended for supervision and assistance to operators during interventions on the dispatcher.

 Of course, the present invention is not limited to the embodiments described and shown but it is capable of numerous variants accessible to those skilled in the art without departing from the spirit of the invention.

In particular, although it has been described with reference to telephone distributors, of which the auxiliary cables have been called "garters", it can be applied to any type of distributor of auxiliary cable lines.

Claims (13)

 1.- Method for controlling a line distributor, characterized in that, to identify a connection made by an auxiliary cable between two fixed connectors of said line distributor, it consists in establishing between these two fixed connectors, in addition to the connection between two lines connected to these two fixed connectors, a connection identifying the connection made by the cable.  2.- Method according to claim 1, characterized in that it further comprises an optical signaling allowing the identification of fixed connectors.  3.- Method according to claim 1, characterized in that, to identify two fixed connectors which must be connected by an auxiliary cable to establish a given connection, it further consists in transmitting two optical signals respectively near these two fixed connectors .  4.- Method according to claim 1, characterized in that, to identify two fixed connectors connected by an auxiliary cable which must be moved or removed, it further consists in transmitting two optical signals respectively near these two fixed connectors.  5.- Method according to claim 1, characterized in that, to identify a fixed connector, it further consists in transmitting an optical signal near this fixed connector.  6.- Auxiliary cable (14) for implementing the method according to claim 1, for connecting two fixed connectors (3, 5; 30, 31) of a line distributor (1), said cable comprising a means of connection (15) between two lines (8, 10) connected to said fixed connectors and comprising, at each of its ends, a movable connector (17, 18) capable of being paired with one of said fixed connectors, this auxiliary cable being characterized in that it comprises a second connecting means (16) for identifying the connection made by the cable.  7.- Cable according to claim 6, characterized in that said connecting means (15) between two lines connected to said fixed connectors is an optical fiber.  8.- Cable according to claim 6, characterized in that the second connecting means (16) for identifying the connection is a metallic conductor.  9.- Fixed connectors for implementing the method according to claim 1, intended to be connected together by an auxiliary cable according to one of claims 6 to 8, characterized in that they each comprise optical signaling means (32 ) allowing their own identification.  10. A line distributor for implementing the method according to claim 1, comprising two strips of fixed connectors and auxiliary cables intended to connect two by two of the fixed connectors of each of the strips, characterized in that it comprises auxiliary cables according to one of claims 6 to 8.  11. A line distributor according to claim 10, characterized in that it further comprises control means (20), means for transmitting (22) and receiving (23) a signal, for transmitting and receiving a signal between two fixed connectors connected by an auxiliary cable, and distributor (26) and selector (27) means, for choosing said fixed connectors.  12. A line distributor according to claim 10, characterized in that it comprises fixed connectors according to claim 9.  13. Line distributor according to claim 12, characterized in that it further comprises signal transmission means (33, 34) for transmitting a signal to the optical signaling means (32) of a fixed connector. , and distributor means (37, 38) for choosing said fixed connector.