DE4125075A1 - Passive optical telecommunications system - has transmission power for each decentralised device controlled by current burst received from exchange - Google Patents

Abstract

The telecommunications system uses a number of decentralised devices (DU) each having a respective optical fibre line (OAL1) coupled to an optical branch coupling (V1) inserted in a common exchange line bus (DB). The signals are transmitted to the decentralised devices (DU) via a burst current, each device (DU) only receiving the related signal bursts, the reception transducer coupled to an operating point regulating circuit for the transmission transducer. Pref. each decentralised device (DU) uses a laser emission diode controlled by an operational amplifier with capacitive feedback. ADVANTAGE - Allows central control of transmission power of each decentralised device.

Description

Recent developments in telecommunications technology result in the level of Subscriber lines to passive optical telecommunications tion systems, in each of which a plurality of decentralized Facilities (participant positions or a plurality of each So-called distant units) with its own fiber optic connection cable optical splitter, which is connected directly or via little At least one more optical branch with a common one Optical fiber connection of - in particular by a mediator given central location via a light waveguide bus is connected (EP-A-01 71 080; ISSLS'88, Conf. Papers 9.4.1 ... 5; BR Telecom Technol. J.7 (1989) 2, 100 ... 113). In such a telecommunication system can transmit signals supply from the central facility (switching center) the decentralized facilities preferably in a burst current (especially ATM cell stream) from which each decentralized facility only for that decentralized facility Establishment of certain bursts (ATM cells); the signal Transfer from the decentralized facilities to the central one Facility (switching center) can in a TDMA procedure decentralized facility everyone Burst (ATM cell) with the help of one from the exchange device-specific delay device sends out synchronized, so that it is at the common light waveguide connection of the central facility (switching do not transfer bursts from other decentralized facilities cuts (EP-A-01 71 080; EP-A-03 18 331; EP-A-03 37 619; DE-P 40 14 396).

In such a passive optical telecommunication system depends on the light output with which the decentralized one light signals emitted in the central facility received from the number of each run  optical splitter - and thus from the configuration of the telephoto communication system - from. This is not a problem if the Light signals from all decentralized facilities the same number run through optical splitters; all decentralized facilities lines can then transmit with the same light output. Generally But one has to take precautions that in the central of the Light signal receiver not from a decentralized facility ago, the z. B. only a single optical splitter the central facility is connected, is overridden and then also for the next one, possibly over a plurality of optical splitters connected to the central facility dene decentralized device in its reception sensitivity is impaired.

To counter this, such telecommunications system regulating the transmitted light output of the decentralized one direction from the central exchange via Downstream telemetry path can be effected (ISSLS′88 op. Cit., P.9.2; British Telecommunications Engineering 7 (1989) 4, 237..241, p.228), what in practice, however, with a considerable circuit tech African effort is connected because u. a. fast A / D and D / A converters are required.

In contrast, the invention shows one way to one less agile control of the transmitted light output in the decentralized on directions of such a telecommunications system.

The invention achieves this with a circuit arrangement for controlling the transmitted light power in a decentralized device Distant Unit | of a passive optical telecommunications system, in each of which a plurality of decentralized devices | Distant Units | is each connected to an optical splitter via its own optical waveguide connection line, which is connected directly or via at least one further optical splitter to a common optical waveguide connection of the central device, in particular the switching center, via an optical waveguide bus,
wherein the signal transmission from the switching center to the decentralized devices preferably takes place in a burst stream (in particular ATM cell stream) from which each decentralized device receives only the bursts (ATM cells) intended for this decentralized device, and
whereby the signal transmission from decentralized devices to the exchange is preferably carried out in a TDMA process, consequently a decentralized device sends out every burst (ATM cell) with the aid of a delay device set by the exchange so that it is shared The optical waveguide connection of the central device does not overlap with bursts (ATM cells) of other decentralized devices, which is characterized in accordance with the invention in that in the decentralized device the optoelectric converter acted upon with the received light signal is connected on the output side to a control input of the operating point control circuit of the electro-optical converter. so that its operating point is set in accordance with the light output received in the decentralized device from the central device.

In a further embodiment of the invention, the one with the reception light signal applied to the optoelectric converter on the output side also with a control input of the modulation circuit of the be connected to the electro-optical converter, so that the modula Degree of transmission light according to the decentralized Facility received light from the central facility power is set.

The invention, which takes advantage of the fact that in the optical branching light both transmission directions one Experience damping brings the advantage, even without one Regulation of the transmitted light output of the decentralized facilities the transmission light output from the central exchange a decentralized device with insufficient damping like to increase and with too high damping, so that even in a network with branches of very different attenuation Level differences under z. B. 10 dB can be kept without that there is a loss of sensitivity.

Further special features of the invention will follow from the  the more detailed explanation of an embodiment according to the Er invention can be seen from the drawings. Show

Fig. 1 is a schematic of a passive optical telecommunications system and

Fig. 2 circuitry details of a provided in a decentralized len facility of such a telecommunications system circuit arrangement for controlling the transmission light output.

In Fig. 1 is shown schematically to an extent necessary for understanding the invention, a bidirectional fiber optic telecommunications system with a passive (preferably single-mode) fiber optic bus network BPON, which is located between a central telecommunications station, for which here a switching center VSt, and a plurality of decentralized Telekommunikationseinrichtun gene, for which so-called. Distant Units ..., DU 2 , DU 3 , ... stand.

Such distant units can, as is also indicated in FIG. 1, be an interface device provided with an electro-optical / opto-electrical converter, which are not shown in FIG. 1 with the aid of an on the electrical side of the converter Multiplexers / demultiplexers may combine or split up to 32 ISDN B channels.

In this fiber optic telecommunications system, the distant units DU are connected to a common fiber optic multiplex connection of the switching center VSt via a single-fiber optical fiber bus OB; the device-specific fiber optic connection lines OAL 1 , ..., OALn may be above - e.g. B. brought in cable junction boxes housed - passive, ie not wavelength-selective, optical splitters V 1 , ... Vn connected to the associated fiber-optic bus OB, either directly or via other such splitters. Through mixers or optical directional couplers, for example, can be used as optical splitters. It is also possible to provide a common optical branching connector for a plurality of device-individual fiber optic connecting lines, as is known per se (for example from EP-A-01 71 080) and therefore need not be described in more detail here .

In the telecommunications system outlined in FIG. 1, a wavelength separation operation (bidirectional wavelength division multiplexing) is provided for directional separation by downward signal transmission from the central telecommunications station VSt to the decentralized telecommunications stations ..., DU 2 , DU 3 , ... Light of a first wavelength λ 1, for example in the 1500 nm band, and for signal transmission in the upward direction from the decentralized telecommunication points ..., DU 2 , DU 3 , ... to the central telecommunication point VSt towards a slightly smaller one, for example in 1300 nm band lying second wavelength λ 2 is used. For this purpose, a corresponding, suitably formed by a laser diode electro-optical converter e / o and a corresponding, appropriately formed by an avalanche photodiode or a pin photodiode optoelectric converter eo are provided in the switching center VSt forming the VSt, which are provided with the associated LWL bus OB are connected via a wavelength-selective optical filter F, for example an optical switch module which is known (for example from US Pat. No. 4,790,616) and is provided with an interference beam splitter.

In a corresponding manner, as is also indicated in FIG. 1, the decentralized telecommunication points, namely the distant units ..., DU 2 , DU 3 , ..., may be provided with electro-optical / opto-electric converters o | e, whose electrical signal output in Fig. 1 (and also in Fig. 2) is denoted by a and the electrical signal input is designated by m.

In the outlined telecommunications system, as is also indicated in Fig. 1, the signal transmission from the switching center VSt down to the decentralized device ..., DU 2 , DU 3 , ... down in a burst current Z _down , for example an ATM cell stream, in front of it. ATM cells of this type (each comprising 53 bit octets) consist of a (5 octet) control information field (header) and a (48 octet) useful information field. Part of the header is the so-called Virtual Path Identifier (comprising 16 bits); Another part of the header is the so-called Access Control Field.

In the ATM cell stream Z _down , synchronization cells with a predetermined bit pattern for synchronization of the decentralized devices can be faded in by the respective cell start (so-called pure ATM), but no ATM, but it is also possible that the ATM Cell stream in turn is embedded in a (e.g. SONET) time frame structure with synchronizing signals (overhead) occurring at certain fixed intervals (so-called frame structured ATM).

From the burst stream (ATM cell stream) Z _down each decentralized device DU takes only the bursts intended for it, in the example those ATM cells that have their header, preferably in its Virtual Path Identifier, with a decentralized device Labeling assigned to DU are addressed. In the drawing, the subdivision in the header and useful information field is illustrated for four ATM cells of an ATM cell stream Z _down, the indications ( 3 , 3 , 2 , n) indicated in the headers of these four ATM cells being used to indicate that the - carrying useful information A and B - the first two cells are intended for the decentralized device DU 3 , that the - carrying useful information C - the third cell is intended for the decentralized device DU 2 and that the - carrying useful information D - fourth Cell is intended for a decentralized device that is no longer shown in the drawing and is reached via the fiber-optic subscriber line OALn.

In the reverse direction of transmission, the signal transmission goes from the decentralized devices | Distant Units | DU upwards to the switching center VSt in a TDMA process with bursts (possibly ATM cells) Z _{up in} front of it, consequently a decentralized device DU transmits each burst synchronized with the aid of a delay device set individually by the switching center VSt , so that each burst is transmitted in a time slot (time slot) re served for the decentralized device DU and a burst at the common fiber optic connection of the central device VSt does not overlap with bursts of other decentralized devices (DU). Such synchronization of the decentralized devices DU is already described elsewhere (EP-A-01 71 080; EP-A-03 18 331; EP-A-03 37 619; DE-P 40 14 396) and therefore does not need to be used here to be discussed further.

In addition to the correct timing of the light signals transmitted by the decentralized facilities ..., DU 2 , DU 3 , ... to the central facility VSt, it is now also important that the light signals arrive at the switching center VSt with a strength that can be detected by them: The optoelectric converter eo of the switching center VSt must not be overdriven, nor can the sensitivity of the central device be overwhelmed. This is particularly important if the individual decentralized devices ..., DU 2 , DU 3 , ... partly over larger, partly over less large rows of optical splitters, sometimes only over a single optical branch, with the central one A direction VSt are connected.

For this purpose, the optoelectrical / electro-optical converter o / e is now implemented in the decentralized device DU in such a way that the optoelectric converter acted upon with the received light signal is connected on the output side to a control input of the operating point control circuit of the electro-optical converter, so that - taking advantage of the circumstance that in the optical branches Ver the light of both directions of transmission is damped - its operating point is set in accordance with the light output received in the decentralized device DU from the central device VSt. An exemplary embodiment of such a circuit arrangement is outlined in the drawing in FIG. 2: According to FIG. 2, in the decentralized device (DU in FIG. 1) there is, for example, an optoelectric converter ED which is provided by a pin diode and which is connected to the decentralized device in question device received light signal is applied, connected on the output side to a control input of an operating point control circuit A, which controls the operating point of the electro-optical transducer SD, for example given by a laser diode, in such a way that its operating point according to the EDO of the optoelectrical transducer central device (VSt in Fig. 1) ago received light output is set. For this purpose, as is also indicated in FIG. 2, the bias current i _{bias of} the laser transmitter diode SD can be controlled by a capacitively negative-coupled operational amplifier IDV, which acts as an integrator or averager, with its inverting input (-) the receiving photodiode ED is connected. This connec tion runs in the embodiment of FIG. 2 via a decoupling amplifier V 1 and one of these controlled, in a manner known per se (see, for example, Tietze - Schenk "semiconductor switching device technology", 6th edition, Fig. 5.20) a resistor R 11 and a field effect transistor R 12 formed voltage divider and a subsequent, connected as a voltage follower ge-coupled operational amplifier. The non-inverting input (+) of the capacitively negative-coupled operational amplifier IDV is connected to a monitor photodiode MD which is loaded with a transmitted light component and which, in a manner known per se (see, for example, telcom report 6 (1983), supplement "Message transmission with light", 90. .96, Figure 4) participates in the setting of the bias current of the transmitter laser diode SD.

The laser transmitter diode SD is modulated by a modulation circuit M, which may be supplied with the modulation signal at an input m (corresponding to m in FIG. 1) and which imposes the bias current i _bias on the laser transmitter diode from the operating point control circuit A. SD also applied a modulation current i _mod . As can also be seen from FIG. 2, the modulation circuit M can be formed with a differential amplifier driven by the input m with two emitter-coupled transistors T 1 , T 2 .

In the exemplary embodiment outlined in FIG. 2, the receiving photodiode ED with the receiving light is now connected via a decoupling amplifier V 2 and a voltage divider realized with an ohmic resistor R 21 and a field effect transistor R 22 to the control electrode of one in the common emitter branch of the two transistors T 1 , T 2 of the differential amplifier MDV lying third transistor T 3 connected. This connection, which leads from the optoelectric converter ED acted upon by the received light signal to a control input of the modulation circuit M of the electro-optical converter SD, also ensures that the degree of modulation of the transmitted light of this electro-optical converter SD in accordance with that in the decentralized device (DU in FIG. 1) received from the central device (VSt in Fig. 1) ago light output is set. This results in a variation of the degree of modulation depending on the reception light, which makes it possible to counteract any distortions caused by the shift in the working point depending on the reception light.

The circuit arrangement outlined in FIG. 2 then works in principle as follows:
With increased received light output and thus higher received current i _ED , the control potential at the gate electrode of the field effect transistor R 12 drops, with the result that the drain-source resistance of the field effect transistor R 12 - and thus also the potential occurring at the voltage divider tap - increases; A higher potential therefore reaches the negating input of the operational amplifier IDV via the subsequent voltage follower, with the result that its output potential drops, so that the subsequent transistors become less conductive and thus lower the bias current i _{bias of} the laser transmitter diode SD.

At a lower received light power and thus reduced receive current i _ED , the control potential at the gate electrode of the field effect transistor R 12 increases, with the result that the drain-source resistance of the field effect transistor R 12 - and thus also the potential occurring at the voltage divider tap - decreases; A higher potential therefore reaches the negating input of the operational amplifier IDV via the subsequent voltage follower, with the result that its output potential increases, so that the subsequent transistors become more conductive and thus increase the bias current i _{bias of} the laser transmitter diode SD.

Claims (4)

1. Circuit arrangement for controlling the transmitted light power in a decentralized device Distant Unit | (DU) of a passive optical telecommunication system, in each of which a number of decentralized facilities | Distant Units | (DU) each has its own fiber optic connection line (OAL 1 , ..., OALn) connected to an optical branching device (V 1 ... Vn), which directly or via at least one additional optical branching device with a common fiber optic connection central device, in particular switching center (VSt), is connected via an optical fiber bus (OB),
wherein the signal transmission from the switching center (VSt) to the decentralized devices (DU) preferably takes place in a burst stream from which each decentralized device (DU) only receives the bursts intended for this decentralized device (DU), and
whereby the signal transmission from the decentralized devices to the switching center (VSt) preferably takes place in a TDMA process, consequently a decentralized device (DU) sends out each burst with the aid of a delay device set individually by the switching center, so that it is transmitted at the common light waveguide connection of the central facility (VSt) does not overlap with bursts of other decentralized facilities (DU), characterized in that
that in the decentralized device (DU) the optoelectric converter (ED) acted upon with the received light signal on the output side is connected to a control input of the working point control circuit (A) of the electro-optical converter (SD), so that its working point in accordance with the direction in the decentralized device (DU) from the central device (VSt) received light output is set. 2. Circuit arrangement according to claim 1, characterized, that the bias current of a laser transmitter diode (SD) from a capacitive negative feedback operational amplifier (IDV) is controlled, with its inverting input (-) one with the receiving light  signal acted upon photodiode (ED) is connected and with it non-inverting input (+) one with a transmitted light component acted upon photodiode (MD) is connected. 3. Circuit arrangement according to claim 1 or 2, characterized, that the optoelek applied with the received light signal trical converter (ED) on the output side also with a control input of the modulation circuit (M) of the electro-optical wall lers (SD) is connected, so that the degree of modulation of Transmitting lights in accordance with the in the decentralized facility (DU) Lichtlei received from the central facility (VSt) is set. 4. A circuit arrangement according to claim 2 and 3, characterized in that the modulation current of the laser transmitter diode (SD) by a differential amplifier (MDV) acted upon by the modulating signal with two emitter-coupled transistors (T 1 , T 2 ) and one in their common emitter branch lying third Tran sistor (T 3 ) is supplied, with the control electrode of which the photodiode (ED) acted upon by the received light signal is connected.