DE4214375A1 - OPTICAL SUBSCRIBER CONNECTING NETWORK WITH WAVELENGTH MULTIPLEX AND MULTIPLE-DUTY OPTICAL MULTIPLEXER / DEMULTIPLEXER - Google Patents

Abstract

A passive optical network, arranged between a central station and the subscribers, is used for transmission in both directions. The central station is connected to an exchange. The passive network has subscriber branching points and several subscriber connections connected to these points. Optical carriers of different wavelengths are provided both for the subscriber connections and also for out and return channels of a connection. Optical multiplexer/demultiplexers are provided for combining and/or dividing the signals to be transmitter. In multiplex mode these have n optical inputs and one output. In demultiplex mode they have one input and n outputs. The carriers for each direction are combined into one group. The groups have different arrangements for their frequency ranges. For the individual contacts different carriers are provided for incoming and outgoing channels. ADVANTAGE - Simple, efficient and inexpensive system.

Description

The invention relates to an optical subscriber line network according to the preamble of claim 1. From time Schrift ntz, volume 44 (1991), volume 4, pages 262-268 an optical subscriber line network known in which a switching device connected to a central unit which is, among other things, an electro-optical conversion carries out and the generated optical signal via a passive optical network with fiber optic cables and cable distributors leads to subscriber positions that are for one or more other participants perform the optoelectronic conversion. In this case, the passive optical network is used in both Directions used, it is of course also possible for separate optical connection for both transmission directions provisions. For economical double use is a fiber for both transmission directions as a multiplex method for interactive services, i.e. ins especially for the telephone signal transmission, the time multi plex procedure provided. Here, the digital Form available information for all participants in one common framework summarized and in time division sent to each subscriber station in which the closed participants except certain information changed, processed and sent to the participants as analog signals be directed. Towards the subscriber to the operator is the information transmission due to the spatial ver shared arrangement of participants more difficult since several Access to the transmission medium simultaneously fen, so that in this state of the art from the satellite Litentechnik known time multiplex method with multiple access is provided.  

From the publication by British Telecom Research Laboratories by A.M. Hill "An Experimental Broadband And Telephony Passive Optical Network "is another opti cal subscriber network known in which instead of egg nes time division multiplex system provided wavelength division multiplex is. This makes it high and code-independent and thus guaranteeing future-proof transmission capacity tet, but there are either complex filter arrangements or a correspondingly tuned optical receiver is required Lich or there are in individual, in the direction of transmission the preferred branching arranged at the subscriber stations score optical demultiplexers. An essential one Saving results in particular when such Mul tiplexer for a certain number of participants together are provided. But since from these demultiplexers to Participants separate glass fibers for both the out and must also be provided for the reverse direction results a comparatively high expenditure of glass fibers corresponding splices, couplings and possibly participat filter, the optical demultiplexer very expensive due to the large number of connections.

Ambiguous optical multiplexers and demultiplexers are like this probably in the form of Fabry-Perot interferometers from DE-A-1- 39 29 480 as well as in the form of combined multiple Zehnder interferometers from IEEE Journal on Selected Areas in Communications Vol. 8, No. 6 of August 1990, pages 1120 to 1127 known, the ambiguity relates doing repetitions in the pass band in certain Frequency spacings, optical gratings can also be used that are operated in a higher order.

The invention is therefore based on the object optical subscriber access network with wavelength division multiplex, thus also an optical multiple star network with several Branching points to reduce the effort.  

According to the invention the object is achieved in that the optical subscriber network mentioned above through the specified in the characterizing part of claim 1 male is trained.

The invention has the advantage regardless of the type of electrical signals to be transmitted, so that in addition to increase the transmission capacity also time-division multiplexing or code division multiplexing applied can be. Appropriate training of the fiction According to the optical subscriber access network are in the patent claims 2 to 7 described in more detail.

The invention will be described in the following with the aid of a voltage illustrated embodiment explained in more detail will.

It shows

Fig. 1, the system image for a first erfindungsge mäßes subscriber access network,

Fig. 2 shows the frequency scheme provided in the optical subscriber line network according to Fig. 1 and

Fig. 3 shows the system picture for a further subscriber access network according to the invention.

In the arrangement according to FIG. 1, the central unit CU connected to the local exchange for the individual subscribers is included, the electrical inputs E1 corresponding to the individual subscribers and connected to the local exchange. . . En has. Each of these inputs has an associated electro-optical converter S1. . . Sn connected, at the outputs of an optical output signal corresponding to the electrical input signal with the wavelength L1 L2. . . Ln is pending, which is output to an assigned input of a first combined multiplexer-demultiplexer MD1, which is a conventional wavelength multiplexer. If necessary, an optical wavelength division multiplexer with a lens system and reflecting diffraction grating can also be used, as described, for example, in DE 32 39 336 A1.

The summarized optical signals are emitted from the output AE0 of the first optical multiplexer MD1 to the connected passive optical network, which is shown in the figure by the optical waveguide, an additional optical branching device ZVZ and by the second optical multiplexer / demultiplexer MD2. This second optical multiplexer / demultiplexer MD2 contains a more clear optical multiplexer in the form of a Fabry-Perot interferometer or a combined multiple-Mach-ten-der interferometer, as described, for example, in the aforementioned IEEE Journal and Selected Areas in Communications, Vol. 8 , No. 6, August 1990 in Figs. 8 and 10 is shown. The demultiplexer outputs of the second multiplexer / demultiplexer MD2 are via optical fiber F1. . . Fn either directly or via subscriber distributors with optical subscriber connections TS1. . . TSn connected to each of which an optical signal with a specific wavelength L1. . . Ln is delivered. With additional use of time-division multiplex transmission with multiple access (TDMA) associated with the de multiplexer outputs of the second optical multiplexer / de multiplexer MD2 associated inputs of subscriber despairers TVZ, which simultaneously deliver the optical signal of one wavelength to several optical subscriber line locations. Each of the subscriber lines TS1. . . TSn contains a comparatively simple wavelength division multiplex filter WDM1. . . WDMn, which is designed as an interference filter in the exemplary embodiment and for separating the received signal of the respective subscriber T1. . . Tn of the sem transmit signal is used. Filter the individual wavelength division multiplex WDM1. . . WDMn are each an optical receiver R1. . . Rn or an optical transmitter T1. . . Tn downstream, in which the electro-optical or opto-electrical conversion of the subscriber signals is carried out.

The electrical signal generated by the respective participant arrives from the optical transmitter T1. . . Tn of the respective op table subscriber connections via the upstream world length multiplex filter on the optical subscriber Connection with the second optical multiplexer / demultiplexer MD2 connecting optical fiber F1. . . Fn, for everyone optical subscriber line and also - if provided - only once for each optical subscriber distributor TVZ is seen, i.e. common to both directions of transmission is used. From the second multiplexer / demultiplexer MD2 become the transmission signals of the individual subscriber connections combined and via the connected optical fiber FO or additional splitters on the combined output Input terminal AE0 of the first multiplexer / demultiplexer MD1 released. From the first multiplexer / demultiplexer the received optical subscriber signals accordingly shared on designated output connections to assigned opto-electrical converter E1. . . En submitted that a ent generate speaking electrical output signal to the assigned electrical output connections A1. . . To the Forwarding or is available to a switching center.

The use of wavelength division multiplexing on the connection lines between second multiplexer / demultiplexer MD2  and optical subscriber lines TS1. . . TSn is not possible without further ado, but sets a match de Dimensioning of this second multipexer / demultiplexer and a dependent choice of which to use for transmission th wavelengths L1. . . Ln, Ln + 1. . . L2n ahead.

FIG. 2 is used for explaining the following embodiments, in which the frequency scheme of the subscriber access network of FIG. 1 is shown, while the optical frequency is Fre with OF and whose amplitude denoted by OA. From Fig. 2 it can be seen that the optical multiplexer / demultiplexer considered has a number of transmission bands, which are usually referred to as orders and are designated in Fig. 2 with i-1, i, i + 1, i + 2 . The majority of the orders make it clear that this is an ambiguous optical multiplexer, the width of the pass band of each order is also referred to as the "free spectral range" (FSR).

According to the invention, all optical carriers for the downlink to the subscriber line are, in Fig. 1, the carrier with the wavelengths L1. . . Ln, combined into a group and also the optical carriers for the reverse direction, which in FIG. 1 with Ln + 1. . . L2n are designated. The optical carrier groups are now with respect to the multiplexer / demultiplexer in different orders in the spectral range of this multiple xer. In addition, the two carriers assigned to a subscriber connection for the forward and reverse direction are at the same points in the respective free spectral range, but in a different order, as is the case in FIG. 2 for the two carrier groups L1, Ln +1 of the first optical subscriber line TS1 is shown.

It follows from these design rules that with a noteworthy number of optical channels and thus optical channels ger and a not too narrow channel spacing of, for example 2 nm the wavelengths for the back and forth direction of a optical subscriber line so far apart that the separation with commercially available interference filters is possible with the participant. The channel spacing can ver by choosing further apart orders be enlarged.

With additional use of time division multiplex transmission are an optical carrier for the back and an optical Carrier for the reverse direction of the group of optical Assigned subscriber lines that have a common Subscriber splitter with the second optical multiplexer / Demultiplexer MD2 are connected. The individual optical Subscriber connections then contain additional electrical connections Multiplex / demultiplexing devices and synchronization arrangement mentions.

In FIG. 3, optical multiplexers / demultiplexers are used not only on the user side but also on the office side in the central unit. In Fig. 3, the central unit CU contains a third multiplexer / demultiplexer MD3, which is constructed in the same way as the second multiplexer / demultiple xer MD2 which is still used on the subscriber side, that is to say has the same free spectral ranges and the same orders. The position of the optical carriers selected with regard to the second multiplexer / demultiplexer MD2 can thus also be retained in the central unit CU. In the central unit, the optical-electrical and the electro-optical conversion in exchange lines A1. . . Made to the largely the subscriber lines TS1 in their structure. . . Correspond to TSn, whereby the filters provided in the subscriber connections may be omitted.

Consistent use of ambiguous optical Multiplexers / demultiplexers allow significant savings conditions for the optical cabling of the subscriber connections and also a significantly lower effort in the central unit CU, which is there mainly in the lower up wall expresses for the optical plug connections.

Claims (7)

1. Optical subscriber line network with wavelength multiplex and ambiguous optical multiplexer / demultiplexer with at least one central unit connected to a switching device, at least one branching from the central unit in the direction of the subscriber lines, which is a passive optical network with near-subscriber optical branching points and a plurality of the latter on closed subscriber lines, optical carriers of different wavelengths being provided both for the subscriber lines with one another and for the back and forth channel of a subscriber line,
characterized,
that ambiguous optical multiplexers / demultiplexers are provided for the combination and / or division of the signals to be transmitted, which have n optical inputs and one optical output in multiplex operation and one optical input and n optical outputs in de multiplex operation,
that all optical carriers for one direction of transmission on the one hand and all optical carriers for the other direction of transmission on the other hand are each grouped together,
that these two groups of optical carriers are rich with respect to the respective ambiguous optical multiplexer / demul tiplexer in different orders of its frequency range and
that for the individual subscriber line different optical carriers for the two transmission directions are easily seen, which are in the same place in the respective free spectral range of the intended ambiguous optical Mul tiplexer / demultiplexer. 2. Optical subscriber line network according to claim 1, characterized, that the ambiguous optical multiplexer / demultiplexer are included in the central unit. 3. Optical subscriber line network according to patent claims 1 or 2, characterized, that the ambiguous optical multiplexer / demultiplexer in direct connection with the subscriber lines are arranged. 4. Optical subscriber line network according to claim 3, characterized, that the ambiguous optical multiplexer / demultiplexer either directly or via optical branch points with are connected to the subscriber lines. 5. Optical subscriber access network after one or several of claims 1 to 4, characterized, that as an ambiguous optical multiplexer / demultiplexer Fabry-Perot interferometers are provided. 6. Optical subscriber line network after one or several of claims 1 to 4, characterized, that as an ambiguous optical multiplexer / demultiplexer combined multiple Mach-Zehnder interferometer featured are seen. 7. Optical subscriber line network according to claim 1, characterized, that as an ambiguous optical multiplexer / demultiplexer Grid filters are provided.