DE3503364A1 - Data distribution network with active optical star couplers - Google Patents

Abstract

In a data distribution network for the transmission of data of one subscriber to the other subscribers, with active optical star distribution by means of hybrid couplers in which the internal distribution is performed electrically and an optical transceiver is used to form the electric level for each star arm, at least one active optical star coupler is provided, the transceivers of each star coupler being interlinked in each case by an electrical switching network in such a way that the signal received via a data line is forwarded not to its own transmitter but only to the transmitters of the other transceivers. The star couplers decoupled from one another in this way are thereby cascadable and the data distribution network can be extended as required in a simple and inexpensive manner by a plurality of star points and can be matched to the topological characteristics of individual cases. Furthermore, a simple means of identifying data collisions is thereby provided.

Description

Data distribution network with active optical star couplers

The invention relates to a data distribution network for the transmission of data one participant to the other participants, with active optical star distribution by means of hybrid couplers, in which the internal distribution takes place electrically and an optical transceiver to form the electrical level for each star branch is used.

Such a data distribution network is from DE-OS 32 41 942 (cf. especially FIGS. 3A-3C with associated text) are known.

Compared to data distribution networks with passive star couplers such as she for example in the company magazine "Fiber Optics Now" of the company CANSTAR, Vol. 5 No. 1, 1983 (document 1) and the prospectus for a "Net 10 Transmission System "by Siecor Fiber LAN, 1983 (publication 2) are disclosed and at which the input light power evenly on a variety of output lines is divided so that the number of participants according to the available light output limited and an extension can only be achieved with great effort, can this data distribution network because of the complete generation of signals in each transceiver can be expanded as required.

However, in each of these known data distribution networks, only one only star coupler to be used because its output signal is inadmissible Way would superimpose the echo signals of the other star couplers (see e.g. Fig. 3 of publication 1 with associated text).

In practice, especially for economic reasons, it is in many cases (e.g. on a university campus with several institute buildings) desirable, one corresponding to the number of buildings Number of star couplers to be used because the lines from the star coupler to the individual participants of a building run only in this itself and are therefore considerably shorter as lines from a central star coupler to all participants. At the stand the technology would have to use several (sub) networks for this in an extremely complex manner very expensive coupling electronics are summarized.

Furthermore, the detection of collisions (two or more participants simultaneously feed data into the network) with digital data transmission on networks, those according to the frequently used CSMA / CD (Carrier Sense and Multiple Access / Collision Detection) principle are built, complicated and in particular in the prior art in the case of the embodiment known from publication 2 in most practical cases prohibitively expensive.

The invention is based on the object of providing a data distribution network to create the preamble of claim 1, which is as simple and as possible cost-effective way through several star points expandable as required and to the topological Can be adapted to the circumstances of the individual case and in the case of digital data transmission a collision detection is possible with the least possible effort.

This object is achieved in that at least one active optics shear star coupler is provided and the transceivers with each other in such a way an electrical coupling field are linked that the received on a star branch Signal not to its own transmitter, but only to the transmitters of the other transceivers got.

This is a simple and effective way to avoid that on the each receiving star branches echo signals are fed back, so that the star coupler are decoupled from each other and can therefore be cascaded. Data distribution networks of the input The type mentioned can thus be expanded as required and accordingly - even at a later date the respective conditions by minimizing the cable lengths optimally cost-effective be designed.

In individual cases there are even savings due to the lower cable attenuation achievable.

In addition, the invention enables digital data transmission according to the CSMA / CD method, the necessary detection of data collisions with the simplest Means, namely according to that known from electrical distribution networks (e.g. Ethernet) Procedure.

In the case of DE-OS 32 41 942 and document 1 obvious Data distribution networks, on the other hand, have to be used with more expensive methods in which the different transit times of the sent and the reflected own Signal from each transceiver in the event of a superposition (collision) with at least one other signal must be taken into account.

A collision detection in the star coupler itself, as it is for example is given in the last image of the publication 2, requires one more essential higher effort, since measures or measures in addition to the collision detection circuit Facilities are required that generate a collision signal (JAM signal) from it, forward this to the participants and evaluate it there.

The subclaims are advantageous designs and refinements of the data distribution network according to the invention.

Particularly efficient and inexpensive to manufacture and use is the data distribution network if, according to claim 2, the transceivers are mechanical and have the same electrical structure. Due to the uniqueness, it is also a cheap one Storage and problem-free interchangeability or expandability of such data distribution networks achieved.

A very useful embodiment is according to claim 3 of the per se known plug-in card structure, which is familiar to every person skilled in the art, wherein the plug-in cards for example, are arranged in 19 "racks and the coupling field on a circuit board set up as a matrix and preferably as simple and inexpensive backplane wiring of the 19 "frame with the connector parts permanently attached to the device (e.g. socket strip) is conductively connected.

In claims 4 and 5 are two alternatives for the link of the lines leading to the transmitters of the transceivers. When linking In the switching network itself, an embodiment as a diode matrix is expedient, with one "Or" function is implemented and each of the connection points of a receiver is unequipped with its own transmitter.

In contrast, the second solution according to claim 5 has an even lower one Space requirements and material costs because there are fewer cables and on the device side Part of the card connector fewer poles are needed and, especially with one Large number of star branches, because there is no need to assemble diodes, less manufacturing costs is required.

The figures show an embodiment of the data distribution network according to the invention for part of a university campus with three institute buildings. they provide in each case a schematic representation of the topological arrangement of the data distribution network (Fig.l) or the transceiver of the star coupler connected by a coupling network in the first institute building, with only two of the a total of five transceivers are drawn.

In the depicted part of the university campus lie in mutual Three institute buildings G1, G2 and G3 with four, five or six participants T1 ... T4, T7 T12, T15 ... T19 (computers, printers, screen terminals, Storage), which are connected to each other bidirectionally through a data distribution network. This is structured in such a way that an active optical star coupler in each building G1, G2, G3 SK1, SK2, SK3 with internal subscribers T1 ... T4 T7 ... T12, 15 ... T19 via short optical data lines (star branches) L1 ... L4 L7 ... L12, L15 ... All9 is connected and the star coupler SK1, SK2, SK3 by electrical data lines L5.6> L13.14 are cascaded. This way is opposite to the from the stand cases known in the art with only one central star coupler from which to a data line leads to each subscriber, a considerable saving in optical terms Cable reached. In addition, this data distribution network is through Further, either in the existing buildings G1, G2, G3 themselves or in additional buildings accommodated participants can be easily expanded as required. In addition, however necessary that the in the star couplers SK1, SK2, SK3 in one of the number of each corresponding number of transceivers contained on these connected data lines SE1 ... SE5, SE6 ... SE13 and SE14 ... SE19 are electrically linked in such a way that that the data signal received via a data line L1 at a receiver E1 is not reaches its own transmitter S1, but only to transmitters S2 ...

13 57 ... 513 or S15 ... S19 of the other SE2 S7 ... 5 or 5 of the SE5, SE7 ... SE13 or SE15 ... SE19. This is for every star coupler SK1, SK2 and SK3 a matrix version on a board P1, P2 or P3 constructed switching network K1, K2, K3 provided. The transceivers SE1 ... SE19 are designed as identically structured Euronorm plug-in cards for a 19 "rack, the connector pins of each plug-in card have a corresponding one with the rear wall of the frame permanently connected socket strip BL1 ... BL19 is assigned. The as backplane wiring Inexpensive coupling fields K1, K2, K3 link the transceivers SE1 SE5, SE6 ... SE13 and SE14 ... SE19 via the socket strips BL1 ... BL5, BL6 ... BL13 and BL14 ... to BLl9 such that each receiver is a transceiver connected to the transmitters of all other transceivers of the relevant star coupler is.

In the star coupler SK1 partially shown in FIG. 2, for example the receiver E1 of the transceiver SE1 only with the transmitters S2 to 55, but not linked to its own transmitter S1.

The data lines of the leading to each transmitter, for example S1 Receiver E2 ... E5 each of the other transceivers, SE2 ...

SE5, are in the relevant transceiver SE1 before the transmitter an OR element Dl combined.

The execution of all transceivers SE1 ... SE19 as identically structured Plug-in card slots for 19 "racks ensure cost-effective production as well as reliable and easy handling during assembly or repair or expansion of such systems. In addition, the link offers the associated transceiver via a carried out in the manner described Coupling field has the advantage of a low space requirement and material and manufacturing costs.

Claims (5)

Claims 1. Data distribution network for the transmission of data from a Participant to the other participants, with active optical star distribution by means of Hybrid couplers in which the internal distribution takes place electrically and for formation On the electrical level, an optical transceiver is used for each star branch is that at least one active optical Star coupler (SK1, SK2, SK3) is provided and the transceivers (SE1 ... SE5, SE6 ... SE13, SE14 ... SE 19> each star coupler (SK1, SK2, SK3) in this way in each case an electrical switching network (K1, K2, K3) are linked to one another that via a data line (L1 ... L5.6 L5.6 ... L13 14 L13 14 ... L19) received signal not to own transmitter (S1 ... S5, S6 ... S13, S14 ... S19), but only to the transmitters of the other transceivers got. 2. Data distribution network according to claim 1, characterized in that all The transceivers (SE1 ... 5E19) are mechanically and electrically identical. 3. Data distribution network according to claim 1 or 2, characterized in that that the transceivers (SE1 ... SE5, SE6 ... SE13, SE14 ... SE19) built on plug-in cards and the associated device-side Connector connections (BL1 ... BL5, BL6 ... BL13, BL14 ... BL19) via the als Matrix formed coupling fields (K1, K2, K3) are connected. 4. Data distribution network according to one of claims 1 to 3, characterized in that that the electrical connection of the to each transmitter (51 - S5, S6 ... S13, S14 * - S19) leading lines in the associated switching matrix (K1, K2, K3) takes place. 5. Data distribution network according to one of claims 1 to 3, characterized in that that the electrical connection of the lines leading to each transmitter (S1 S19) in the transceivers (SE1 ... SE19) by means of an "And" or an "Or" gate (01 ... 019) he follows.