DE3437772A1 - System for connecting subscribers to a central station - Google Patents

Abstract

The invention relates to a system for connecting a multiplicity of subscribers (3) to a central station (1) via optical waveguides. The optical waveguides of physically adjacent subscribers are in each case coupled in an out-of-area device via wavelength multiplexers and demultiplexers to a common optical waveguide which is connected to the central station. A dedicated wavelength ( lambda 1 to lambda n) is allocated to each subscriber. Through multiple use of the connection between the central station and the out-of-area device, albeit a purely passive optically selective out-of-area device, the costs of the system can be kept down, its reliability can be increased and its flexibility and extendability can be guaranteed. <IMAGE>

Description

System for connecting participants to a control center

The invention relates to a subscriber line system according to the preamble of the main claim.

Such a subscriber line system is from DE-OS 32 20 817 known. The subscriber line system described there is a distribution network for Television signals in which a large number of participants are connected to a control center and is supplied by this with a plurality of television programs. With this one It is not possible for the system to send individual subscribers individual messages, for example for a videophone connection.

The invention is based on the object of a subscriber line system to be specified, with which subscriber-specific information can also be transmitted.

The object is achieved according to the invention by the teaching of the main claim. Advantageous refinements of the invention can be found in the subclaims.

From DE-OS 32 39 593 a subscriber line system is known, where between a central office and a Apron facility (there Called substation) messages are transmitted in optical wavelength division multiplex will.

The wavelength division multiplex is not used there to generate a Separation of different information to achieve, but to the flow of information overall to be able to increase. At the end of the transfer, the individual Information transmitted in wavelength ranges is summarized again.

In the following the invention is based on embodiments under Further explained with the aid of the accompanying drawing.

As an exemplary embodiment, FIG. 1 shows the minimal configuration of a subscriber line system according to the invention.

FIG. 2 shows, as an exemplary embodiment, a further developed according to the invention Subscriber line system.

The subscriber line system shown in Figure 1 consists of one Central 1, a front-end facility 2, a number of participants 3a to 3n, an optical waveguide 4, which connects the control center 1 with the front-end device 2 and several optical fibers 5a to 5n, through which the participants 3a to 3n individually are connected to the Vorfeld = facility 2.

In the control center 1, each subscriber 3a to 3n is an electro-optical one Assigned converters 12a to 12n. The output wavelengths A1 to An of each electro-optical converter 12a to 12n are chosen so that the individual wavelength ranges do not overlap and that they are in one range lie in which the optical waveguides 4 and 5a to 5n a transmission in sufficient Allow quality. The number of subscribers that can be connected to an optical fiber 4 is primarily due to the selectivity of the individual wavelength ranges separating optical means determined.

The electro-optical converters 12a to 12n are lasers or light-emitting diodes (LED). The input signal of an electro-optical converter 12a to 12n contains the information specific to the associated subscriber 3a to 3n, for example a pulse code modulated time division multiplexed signal which contains the information of a direction of a Includes videophone connection. A second can be reversed for the opposite direction established subscriber line system be available.

The output signals of the individual electro-optical converters 12a to 12n are combined in a wavelength division multiplexer 11. The coupling of the Output signals of the electro-optical converters 12a to 12n in the wavelength division multiplexer 11 takes place via fiber optics.

Any optical means is called a wavelength division multiplexer, with which it is possible to have several optical input signals with different wavelengths to combine into a single optical output signal. Conversely, as Wavelength demultiplexer denotes any optical means with which an optical Input signal made up of different partial signals with different wavelengths composed, can be broken down into these partial signals. A wavelength demultiplexer works thus wavelength selective. The wavelength-selective effect is achieved, for example, by means of wavelength-selective directional couplers or diffraction gratings or achieved by filters, both interference filters and absorption filters are applicable. A wavelength demultiplexer can work in the opposite direction as a wavelength division multiplexer be used. However, the selective effect does not always play a role here Role, so that in some cases even simple fiber fusion couplers can be used. As a rule, however, those embodiments are sought that work in both directions are equally usable and then as wavelength division multiplexers / demultiplexers are designated.

The control center 1 advantageously contains a large number of such devices. Each such device is connected to a front-end device via the associated optical waveguide 4 2 connected, the individual apron facilities 2 usually spatially from are separated from each other.

The front-end device 2 essentially consists of a wavelength demultiplexer 21. At the outputs of the wavelength demultiplexer 21 are those to the participants 3a to 3n coupled optical waveguides 5a to 5n, although this is not excluded is that two or more technical facilities referred to here as participants are not spatially separated and are used by the same operator. The these Wavelength ranges assigned to separate technical devices can be over a common fiber optic cable or a separate fiber optic cable. On everyone The output of the apron device 2 is thus again the same wavelength range present, as at the output of the associated electro-optical converter 12a to 12n. The apron device 2 is not only constructed very simply, it contains even only passive components. Nevertheless, each participant only receives the for information intended for him.

Each participant 3a to 3n has an optoelectronic at its input Converter 31a to 31n, for example a photodiode. 3 the output signal of a each of the opto-electric converters 31a to 31n contains the same information as that Input signal of the associated electro-optical converter 12a to 12n in the control center 1. The information is retrieved using the known methods of transmission technology (e.g. amplification, synchronization, equalization).

The type of fiber optic cable used is of minor importance Meaning. For the optical fiber 4 between the control center 1 and the apron facility 2 a single mode fiber is preferred. To the shorter optical waveguides 5a to 5n between the front-end device 2 and participants 3a to 3n and between the electro-optical Converters 12a to 1Zn and the wavelength division multiplexer 11 in the center 1 no special requirements made.

Depending on requirements, single-mode fibers or gradient fibers are preferred here.

The embodiment shown in Figure 2 is an extension the example according to Figure 1. It shows then a subscriber line system that is similar Allows connections in both directions with just a little extra Effort can be created. There does not have to be a second similar system for the reverse direction must be present. The embodiment shown in Figure 2 is possible assume that the wavelength division multiplexer 11 and the wavelength division demultiplexer 21 are constructed so that both are wavelength selective and in one direction as a wavelength multiplexer and in the other direction as a wavelength demultiplexer works.

Each participant 3a to 3n has in addition to the opto-electrical converter 31a to 31n still have an electro-optical converter 32a to 32n whose optical Output by means of an optical coupler 33a to 33n with the subscriber side End of the optical waveguide 5a to 5n and the optical input of the optoelectronic Converter 31a to 31n is coupled. Correspondingly, there is also 1 in the center for each electro-optical converter 12a to 12n an opto-electrical converter 13a to 13n and an optical coupler 14a to 14n are provided. The decoupling between the output of the electro-optical converter 32a to 32n and the input of the opto-electrical Converter 31 to 31n can either by using different wavelength ranges or through a reflection-free structure of the entire arrangement, especially the optical one Couplers 33a to 33n take place. The same applies to headquarters 1.

The embodiment of Figure 2 can also be modified so that in the center 1 in addition to the wavelength multiplexer 11, a wavelength demultiplexer is present, the outputs of which with the inputs of the opto-electrical converter 13a to 13n are connected.

Its input can then be linked to a single optical coupler Output of the wavelength division multiplexer 11 be connected. Also the opposite side, i.e. the apron device 2 together with the subscriber area connected to it can be constructed accordingly.

Claims (11)

Claims 1. Subscriber line system with a central office; with at least one apron device connected to the control center via an optical waveguide; with a plurality of participants, each via a fiber optic cable the apron facilities are connected; and with optical means in the apron facilities, through which the optical waveguides, which the apron devices on the one hand with the control center and, on the other hand, with the participants, linked to each other are, as is not indicated, that everyone is connected to an apron facility (2) connected participant (3) on which this apron facility (2) with the Central (1) connecting optical waveguides (4) at least one separate wavelength range is permanently assigned; that the optical means (21) in each apron device (2) are wavelength selective (wavelength demultiplexer); and that in the headquarters (1) Means (11, 12) are available via which each participant (3) is assigned to him Wavelength ranges via the subscriber's own means (31) a message transport is possible. 2. Subscriber connection system according to claim 1, characterized in that that the wavelength demultiplexer (21) in the apron facility (2) Contains a diffraction grating. 3. Subscriber connection system according to claim 1, characterized in that that the wavelength demultiplexer (21) in the front-end device (2) is a fiber fusion coupler with downstream optical filters. 4. Subscriber connection system according to one of claims 1 to 3, characterized characterized in that in the center (1) a wavelength division multiplexer (11) as an optical Means is present, which is constructed in the same way as the wavelength demultiplexer (21) in the apron facility (2). 5. Subscriber line system according to one of claims 1 to 4, characterized characterized in that in the center (1) electro-optical converters (12) with different Output wavelengths are available. 6. Subscriber line system according to one of claims 1 to 5, characterized characterized in that the subscriber (3) and the center (1) have means are to in both directions on the subscriber (3) assigned wavelengths Deliver messages. 7. Subscriber connection system according to claim 6, characterized in that that the inputs of the wavelength division multiplexer (11) in the control center (1) are optical Directional coupler connected upstream and the outputs of the wavelength demultiplexer (21) optical directional couplers are connected downstream. 8. subscriber connection system according to claim 6, characterized in that that in the control center (1) and in the field device (2) each one Wavelength division multiplexer and a wavelength demultiplexer is present and that the output of the wavelength division multiplexer and the input of the wavelength division multiplexer, respectively are connected to the optical fiber (4) via directional couplers. 9. Subscriber connection system according to claim 6, characterized in that that between the center (1) and the apron (2) for each direction a separate one Optical fiber is available. 10. Subscriber line system according to one of claims 1 to 9, characterized characterized in that the number of subscribers connected to the required transmission capacity and signal quality is adapted. 11. Subscriber line system according to one of Claims 1 to 10, thereby characterized in that subscribers (3) to which several wavelength ranges are assigned are connected to the apron device (2) via more than one optical waveguide (5) are.