DE2708606C2 - - Google Patents

Description

The present invention relates to Communication process in which information is optically transmitted Optical fibers is transmitted, the optical fibers in addition to the transmission of communication signals also for Transfer from to establishing and clearing a connection required signals are used.

In recent years there has been light consisting of glass fibers waveguides have been developed that allow broadband To transmit signals with comparatively low attenuation. These properties make fiber optic cables particularly special is suitable for use in higher telephone network levels systems in which a larger number of tele phone signals in time-division multiplex or frequency division multiplex technology be transmitted. Are the transmission lines in higher Network levels built from fiber optic cables, but so wins also for the sake of applying a uniform over wearing technology the use of optical fibers in the lower network levels down to the individual subscriber stations in interest. This is especially true, even if for the Subscriber lines need a higher frequency band width exists than the usual electrical telephone part can provide subscriber lines.  

From DE-OS 25 13 606 is a news Transmission system according to the preamble of claim 1 for the transmission of messages between selectable end points using a Network knot linked mesh known Optically transmit information via optical fibers will. In this known arrangement it is provided that signals necessary for the operation of the system be carried over these optical fibers. So be e.g. B. Data relating to a fee level for the Transfer subscriber terminals and displayed in these.

From the magazine "Die Technik", 29th year, issue 7, July 1973, pp. 423-425 and Issue 8, August 1973, pp. 490- 493 is the use of a light wave conductor as an energy conductor known.

From the magazine "Elektronik" 1976, Issue 9, p. 79 is the transfer of energy and control signal over the same Optocoupler known.  

The present invention is based on the object To further develop communication methods according to the preamble of claim 1, that the subscriber stations over the optical fibers with energy be supplied.

To achieve this object, the invention proposes a communica tion method of the type mentioned and according to the preamble of claim 1 according to the invention by the features specified in the characterizing part is true.

The following is an embodiment of the invention on hand described the figure.

The figure shows a subscriber line consisting of an optical waveguide 1 , which connects the subscriber station shown on the right to the control center shown on the left. The subscriber station comprises a device 12 in which an opto-electric converter with an alarm device is integrated, an opto-acoustic converter 13 and an acousto-optic modulator 14 . The optoacoustic wall ler 13 may for example consist of an optoelectric converter, for. B. a photodiode and an earpiece coupled thereto. For the acousto-optical modulator, the known structure comes into consideration, in which - due to the elasto-optical effect - light is scattered on an acoustic wave.

Furthermore, a fork 3 are provided in the subscriber station for merging or separating the forward and return channels, a crossover 10 which supplies the incoming light signal via a fork switch 8 to the device 12 or the optoacoustic converter 13 and which delivers the unmodulated incoming light an optical changeover switch 9 feeds the acousto-optical wall 14 or returns it to the optical fiber 1 via a coupling element 5 and the fork 3 . In the center, a control device 15 and a switching matrix 16 are provided, furthermore a fork 2 for merging or separating the forward and return channels, a coupling element 4 , two electro-optical converters 11 and 11 a and two opto-electrical converters 17 and 18 , an optical switch 6 , the useful information signals to the optoelectric converter's 18 and the operating signals required to set up and clear the connections to the optoelectric converter 17 , and an electrical switch 7 which , depending on the switching position, the outgoing operating signals or the outgoing useful information signals to the electro-optical converter 11 directs.

Instead of one optical fiber, two can be used, one each for the outward and return journey. The forks 2 and 3 can then fall ent.

If a connection to the participant shown in the figure is to be established on the basis of a request from a third party arriving at the central office, the central control unit 15 will control the electro-optical converter 11 a , which, like the electro-optical converter 11, consists of a light source, e.g. B. a luminescent diode, can be driven. Here comes through a light signal via the coupling member 4 and the fork 2 and the optical fiber 1 , the fork 3 , the frequency switch 10 , the fork switch 8 to the Vorrich device 12th Upon acceptance of the communication request by the participant, the hook switch 8 is flipped and at the same time the optical changeover switch 9 is switched so that it supplies the acousto-optic modulator 14 with light. Before this switchover, the coupling member 5 and thus the light guide 1 receives the unmodulated light emitted by the crossover 10 directly, while after the switchover this light is passed through the acousto-optical modulator 14 . By this order, the light intensity is reduced. This reduction in intensity is recognized in the control center by the control device and the connection is then switched through.

If a connection is to be established on the basis of the communication request of the subscriber shown, the changeover switch 9 is briefly brought into a position in which it is possible to send information about a communication request to the center. For this purpose, the unmodulated light arriving from the control center is returned to the control center via the changeover switch 9 .

Thereafter, the changeover switch 9 is switched to supply the acousto-optical modulator 14 and at the same time the fork switch 8 is switched from its rest position to its operating position. In the control center 15 the operational readiness of the subscriber is recognized, the connection request is forwarded and the switches 6 and 7 are switched to the transmission of the useful information.

Claims (2)

1. Communication method in which information is transmitted optically via optical fibers, the optical fibers being used in addition to the transmission of communication signals also for the transmission of signals necessary for establishing and clearing a connection, characterized in that

• - That additionally unmodu liert light is transmitted from a central station to a Teilneh merstation for their energy supply via the optical fibers, the frequency of which differs from the fundamental frequency of the modulated light transmitted from the Zen central station to the subscriber station, and
• - That the arriving in the subscriber station from the central station light is supplied to a crossover network ( 10 ), which receives the incoming modulated light via a hook switch ( 8 ) to an optoacoustic transducer ( 13 ) or to a device ( 12 ) in which an optoelectri shear converter is integrated with an alarm device, and the incoming unmodulated light to an acousto-optical modulator ( 14 ) for generating a communication signal to be transmitted from the subscriber station to the central station.

2. Communication system according to claim 1, characterized in that by means of a between the crossovers ( 10 ) and the acousto-optical modulator ( 14 ) arranged optical change switch ( 9 ) the unmodulated light for signaling a connection request of the subscriber station is returned directly to the central station .