FR2842966A1 - Connection device between an optical fibre and an optical emitter, used in optical communication networks, uses first and second multi-mode optical fibre strands - Google Patents

Abstract

The device includes a connector (32) adapted to be connected to the second connector (18,20) of the optical communication unit (6), a first strand (34) having a multi-mode fibre optical unit in a cladding of this second diameter, and diameter adaptation units (36) connecting and ensuring a continuity of optical path between the first strand and the second strand (38) having a the multi-mode fibre optical unit in the cladding of the first diameter, this second strand being connected to a connector (39) adapted to be connected to this multimode optical fibre unit. The connection device (30) between a multi-mode optical fibre unit in a cladding of a first predetermined diameter and an optical communication device (6), having an optical emitter (14) delivering the optical signal to the connector (18,20) adapted to be connected to an optical fibre in a cladding of a second diameter, different from the first diameter.

Description

I The present invention relates to a device for connecting between

  least a so-called multimode optical fiber and a communication device comprising an optical transmitter, as well as an optical communication system of the type comprising such an optical fiber and such a communication device. Fiber optic networks originally developed with so-called "multimode" optical fibers with a jump in diffraction index

  brutal so as to cause propagation of the optical signals by successive reflections.

  Such fibers are generally in sheaths of large diameters, of the order of ten millimeters, and cause a weakening of

around 1.2 dB / km.

  Typically, the communication equipment used

  with such fibers comprise emitters comprising light-emitting diodes and allowing high power emissions, so as to reach ranges of the order of 15 km.

  Subsequent technological developments have made it possible to design so-called "single-mode" fibers, exhibiting progressive variations in the diffraction index so as to obtain propagation of the optical signals.

  without reflection, thus limiting energy losses.

  Such fibers are generally in sheaths with a small diameter of the order of 3 mm, have a weakening of the order of 0.37 dB / km and

  are used with laser type transmitters.

  Today, all new optical communication installations include single-mode fibers and laser-type transmitters, so that networks using multimode optical fibers are

underemployed, even unused.

  However, the increase in the volumes of information and the limitations on the implantation of new optical fibers linked to regulatory problems and a quantitative insufficiency of materials, lead to saturation of communication systems using single-mode fibers.

and laser type transmitters.

  The present invention aims to remedy this problem, by enabling the rehabilitation of communication networks by optical means using fibers.

"multimode" type.

  The subject of the present invention is a connection device between at least one multimode optical fiber in a sheath of a first predetermined diameter and an optical communication device, comprising an optical transmitter delivering optical signals to a connector adapted to be connected to a optical fiber in a sheath of a second diameter different from said first diameter, characterized in that it comprises a connector adapted to be connected to said connector of the optical communication device, a first strand comprising at least one multimode optical fiber in a sheath of said second diameter and diameter adaptation means connecting and ensuring continuity of the optical path between said first strand and a second strand comprising at least one multimode optical fiber in a sheath of the first diameter, which second strand is connected to a connector suitable for be connected to said at least

multimode optical fiber.

  According to other characteristics: - said strands are bidirectional and each comprise two optical fibers and said connectors as well as said diameter adaptation means are adapted to each connect two optical fibers; - Said first predetermined diameter is of the order of ten millimeters; and

  - Said second predetermined diameter is of the order of 3 mm.

  The present invention also relates to an optical communication system, comprising at least one multimode type fiber in a sheath of a first predetermined diameter and at least one optical communication device comprising a transmitter and multiplexing means of data for transmission in the form of optical signals of predetermined wavelength by the optical transmitter, characterized in that said optical transmitter is a laser type transmitter, in that said optical communication device comprises at least one connector adapted to be connected to an optical fiber in a sheath of a second diameter different from said first diameter, and

  that said system includes a connection device according to any one of claims 1 to 4, disposed between said communication device

  and said at least one multimode type optical fiber, to allow the emission of the optical signals generated by said laser type transmitter, on said au

  minus a multimode type optical fiber.

  According to other characteristics of the system of the invention - said at least one multimode optical fiber has a length of less than 5 km; said at least one multimode optical fiber is included in a bidirectional telecommunication optical loop composed of multimode optical fibers; - It also comprises another bidirectional telecommunication optical loop composed of single-mode optical fibers and forming a normal optical path, said optical loop composed of multimode optical fibers, forming a backup optical path and said optical communication device comprising means switching so as to allow connection to one or other of these optical loops; and - said predetermined wavelength at which said transmitter emits

  optical, is substantially equal to 1310 nanometers.

  The invention will be better understood on reading the description which will

  follow, given only as an example and made with reference to the drawing, on

  which is shown schematically a part of a communication system according to the invention.

  This system comprises a first bidirectional optical loop 2 composed of two “single mode” type optical fibers, one intended for

  the other and the other on receiving information.

  Conventionally, the optical fibers constituting the optical loop

  2 are arranged in a sheath of a small diameter, of the order of a few millimeters, such as for example with a diameter of 3 mm.

  The system further comprises a second bidirectional optical loop 4 made up of two “multimode” type optical fibers, one intended for transmission and the other for reception of information.

  These multimode fibers are arranged in a sheath with a large diameter of the order of ten millimeters, such as for example with a diameter

10 mm.

  The system includes an optical communication device 6 or

  Optical Distribution System, commonly called "SOD".

  This communication device 6 includes an input connector 8

  suitable for receiving digital information.

  This connector 8 is connected to multiplexing means 10 produced in a conventional manner and delivering a multiplexed data stream. These multiplexing means 10 are connected to an optical transmitter 14

  laser type that delivers an optical signal corresponding to the multiplexed data it receives as input.

  In the context of the invention, the laser type transmitter is suitable for

  operate at a wavelength substantially equal to 1310 nanometers.

  The communication device 6 finally comprises signal switching means 16 adapted to switch the optical signals coming from

  the transmitter 14 to one or the other of two output connectors 18 and 20.

  The communication device 6 also comprises means for reception, conversion and demultiplexing, making it possible to receive an optical signal and to extract therefrom a plurality of electrical signals corresponding to

digital data.

  Thus, in a conventional manner, the communication device 6 is adapted to allow the transmission and reception of the optical signals to and from

  either of the two connectors 18 and 20.

  Connectors 18 and 20 are conventionally connectors

  of the same kind suitable for optical fibers in sheaths of small diameter, such as sheaths of single-mode optical fibers of 3 mm in diameter.

  In the example described, the connector 18 is connected in a conventional manner, to the single-mode optical loop 2 via a jumper 22. This jumper 22 is composed of a conventional single-mode connector 24, of a strand 26

  bidirectional comprising two optical fibers in a sheath of 3 mm dia30 meter and a connector 27 connectable to an optical head 28 of the optical loop 2.

  The jumper 22 therefore allows the communication device 6

  send and receive information on and from the single mode optical loop 2.

  Furthermore, the system comprises, according to the invention, means for

  connection 30 between the communication device 6 and the multimode optical loop 4.

  These connection means 30 comprise a connector 32 adapted to be connected to the connector 20 suitable for sheaths of 3 mm in diameter, The connection means 30 then comprise, connected to the

  connector 32, a bidirectional strand 34 comprising two multimode optical fibers in a sheath of 3 mm in diameter.

  This strand 34 is connected to an adapter of diameter 36 allowing the mechanical and optical connection of optical fibers in a 3 mm sheath of

  diameter to optical fibers in a sheath of 10 mm in diameter.

  The adapter 36 is also connected to a bidirectional strand 38 comprising two multimode optical fibers in a sheath 10 mm in diameter.

  This strand 38 of multimode optical fibers in a sheath 10 mm in diameter is connected to a connector 39 adapted to be conventionally connected to an optical head 40 of the optical loop 4 composed of optical fibers

  multimode in a 10 mm diameter sheath.

  The diameter adapter 36, formed by a set of light-conducting sections, is capable of ensuring continuity of the optical path

  between the corresponding optical fibers of the two strands 34 and 38.

  It therefore appears that the connection means 30 allow the

  connection of the connector 20 of the communication device 6 to the multimode optical loop 4.

  Thus, in operation, the communication device 6 transmits an optical signal using the laser transmitter 14, at a wavelength of substantially 1310 nanometers, which optical signal is routed by the switching means 16 to the single-mode optical loop 2, through the jumper

22 in a conventional manner.

  This operating mode constitutes an operating mode

  nominal of such an optical communication system, by a so-called normal optical path.

  However, in the event of failure of the single-mode optical loop 2, the switching means 16 are adapted to switch the optical links

  towards an optical path called emergency.

  In the example described, this optical backup path is formed by the multimode optical loop 4 on which the communication device 6 transmits information using the laser type transmitter 14, at the wavelength of 1310

  nanometers and via connection means 30.

  In practice, it is preferable that the multimode optical loop 4 is

  with a length of less than 5 km and preferably less than 2 km.

  It therefore appears that the system of the invention makes it possible to rehabilitate optical loops composed of multimode fibers, by allowing the transmission and reception of optical signals on these multimode optical loops, using

  Communication devices provided with laser type transmitters and initially intended to be connected to single-mode optical fibers.

  In the example described, the multimode optical loop is used as a backup optical path, thus making it possible to free up single-mode optical loops while allowing continuity of flow in the event of incidents.

  on the main single mode optical loop.

  In other embodiments, only multimode optical loops are used.

Claims (9)

  1. Connection device (30) between at least one multimode optical fiber in a sheath of a first predetermined diameter and an optical communication device (6-), comprising an optical transmitter (14) delivering optical signals to a connector ( 18, 20) adapted to be connected to an optical fiber in a sheath of a second diameter different from said first diameter, characterized in that it comprises a connector (32) adapted to be connected to said connector (18, 20) of the device of optical communication (6), a first strand (34) comprising at least one multimode optical fiber in a sheath of said se10 cond diameter and diameter adaptation means (36) connecting and ensuring continuity of the optical path between said first strand (34) and a second strand (38) comprising at least one multimode optical fiber in a sheath of the first diameter, which second strand (38) is connected to a connector (39) adapted   to be connected to said at least one multimode optical fiber.   2. Device according to claim 1, characterized in that said strands (34, 38) are bidirectional and each comprise two optical fibers and in that said connectors (32, 39) as well as said means for adapting   diameter (36) are suitable for connecting each two optical fibers.   3. Device according to any one of claims 1 or 2, carac20 terized in that said first predetermined diameter is of the order of ten of millimeters.   4. Device according to any one of claims 1 to 3, characterized in that said second predetermined diameter is of the order of 3 mm.   5. Optical communication system, comprising at least one multimode type fiber in a sheath of a first predetermined diameter and at least one optical communication device (6) comprising a transmitter and data multiplexing means ( 10) with a view to their emission in the form of optical signals of predetermined wavelength by the optical transmitter (14), characterized in that said optical transmitter (14) is a laser type transmitter, in that said device optical communication (6) comprises at least one connector (18, 20) adapted to be connected to an optical fiber in a sheath of a second diameter different from said first diameter, and in that said system comprises a connection device (30) according to one   any of claims 1 to 4 disposed between said communication device   cation (6) and said at least one optical fiber (4) of multimode type, to allow the emission of optical signals generated by said transmitter (14) of type   laser, on said at least one multimode type optical fiber (4).   6. System according to claim 5, characterized in that said at least one multimode optical fiber has a length of less than 5 km.   7. System according to any one of claims 5 or 6, characterized in that said at least one multimode optical fiber is included in a   bidirectional telecommunication optical loop (4) composed of multimode optical fibers.   8. System according to claim 7, characterized in that it further comprises another optical loop (2) bidirectional telecommunication, composed of single-mode optical fibers and forming a normal optical path, said optical loop (4) composed of optical fibers multimode, forming an emergency optical path, and said optical communication device (6) comprising switching means (16) so as to allow the   connection to one or other of these optical loops (4, 6).   9. System according to any one of claims 5 to 8, characterized in that said predetermined wavelength at which said optical transmitter emits (14), is substantially equal to 1310 nanometers.