DE102007028208A1 - Network, particularly optical network for data transmission, has electrical and optical star coupler with multiple electrical and optical terminals and terminal of optical star coupler is coupled with terminal of electrical star coupler - Google Patents

Abstract

The network has an electrical star coupler (200) with multiple electrical terminals (201 to 204). The optical star coupler (100) with multiple optical terminals (101 to 103). A terminal of the optical star coupler is coupled with a terminal of the electrical star coupler by an opto-electronic converter (300). An opto-electronic converter is arranged or integrated with the electrical star coupler. An independent claim is also included for a method for data transmission between an optical star coupler and an electrical star coupler.

Description

BACKGROUND OF THE INVENTION

The Invention relates to a network for data transmission. In particular, it concerns the invention a network for data transmission, the optical star coupler includes.

optical Star couplers are known as components of optical networks. One optical star coupler has a plurality of terminals, the input and / or outputs represent the star coupler. An attached to an entrance terminal Optical input signal will be equally applied to the output terminals of the star coupler distributed. It can be provided that input signals different wavelengths the exit terminals are distributed.

It are transmission type star couplers and reflection type star couplers known. With the transmission type, the inputs and outputs are separated arranged from each other while With the reflection type, each input can also act as an output.

A exemplary application for Star couplers are photonic local area networks (LANs) with a star topology.

It There is a need for performance and capabilities optical networks continue to improve.

SUMMARY OF THE INVENTION

In an embodiment The present invention provides an optical network for data transmission provided, the at least one electric star coupler and has at least one optical star coupler. It is at least a terminal of the optical star coupler via an optoelectronic Transducer coupled to a terminal of the electric star coupler. The result is a heterogeneous network topology with electrical and optical network components.

at The optical star couplers are in an embodiment variant passive optical star couplers that do not require a power supply. Basically however, also active optical star couplers usable. The electrical Star couplers are active elements that require a power supply.

A "terminal" of an optical or electrical coupler provides an input and / or output of the Kopplers ready. Each terminal has at least one transmission channel the data transmission assigned. Several transmission channels exist in the case of multiplexing.

In a further embodiment The present invention provides an optical network for data transmission provided, the optical coupling means with a plurality of terminals and electrical coupling means having a plurality of Terminals, wherein at least one terminal of the optical Coupling means with at least one terminal of the electrical coupling means via optoelectronic Transducer is connected.

One another embodiment The present invention provides a method for data transmission between an optical star coupler and an electrical star coupler ready. There is a provision of data at a terminal an optical star coupler, converting the optical data, which are provided at this terminal, into electrical data, and providing the converted data to a terminal of the electric star coupler.

BRIEF DESCRIPTION OF THE DRAWINGS

Several embodiments The invention will be described below with reference to the figures the drawing explained in detail. The drawings are to be understood as being typical only embodiments represent the invention and not limit its scope. Show it:

1 schematically a first embodiment of a compound of an optical star coupler with an electric star coupler, wherein the electric star coupler comprises a bidirectional opto-electronic converter;

2 schematically a second embodiment of the connection of an optical star coupler with an electric star coupler, wherein the electric star coupler comprises a bidirectional opto-electronic converter;

3 schematically an optical network with an optical star coupler, one terminal of which is connected to a gateway to an electrical network;

4 schematically an embodiment of the connection of an optical star coupler with an electric star coupler, wherein two optical channels between the optical star coupler are realized to the electric star coupler; and

5 schematically an embodiment of the connection of an optical star coupler with an electric star coupler, wherein an opto-electronic converter in the optical star coupler is arranged.

DESCRIPTION OF EMBODIMENTS THE INVENTION

The 1 shows a first embodiment of a connection of an optical star coupler 100 with an electric star coupler 200 , The connection may be part of a data transmission network having a plurality of optical and electrical star couplers and corresponding connections.

The The following description considers a passive optical star coupler. However, those skilled in the art will recognize that the teachings described are the same can be realized with an active optical star coupler, for example, has an electrical repeater and therefore requires a power supply. The electric star coupler is an active element that needs a power supply, and will therefore also referred to as active electrical star coupler.

The optical star coupler 100 points in a first frontal coupling region 110 a plurality of terminals 101 . 102 . 103 on, to each of which an optical fiber 401 . 402 . 403 connected. At a second frontal coupling area 120 at one of the first coupling area 110 spaced surface is formed, there is another terminal 104 at which an optical fiber 404 connected.

The active electric star coupler 200 has several electrical terminals 201 . 202 . 203 . 204 on. In the active electric star coupler 200 is an opto-electronic converter 300 integrated, which is an optical terminal 301 having. The output of the opto-electronic converter 300 is electrical and provides one of the electrical terminals of the electric star coupler 200 (not shown separately).

The optoelectronic converter 300 can be designed for a unidirectional data transmission as an optoelectronic receiver unit or as an optoelectronic transmitter unit or for a bidirectional data transmission as a bidirectional optoelectronic converter.

For example, data transfer occurs such that in one or more of the optical fibers 401 . 402 . 403 guided light at the first coupling area 110 into the passive optical star coupler 100 coupled and at the second coupling area 120 from the star coupler 100 is decoupled. The decoupled light is from the terminal 104 over the optical fiber 404 to the opto-electronic converter 300 transfer. This receives the light signals at the terminal 301 and converts the light signals into electrical signals.

It can be provided that according to the number of data channels, are transmitted over the data, a plurality of electrical outputs of the opto-electronic converter 300 are provided. For example, in the unit 300 integrated a multiplexer / demultiplexer which separates the individual wavelengths, and is further provided for each wavelength an optoelectronic transducer with an electrical output. The one or more electrical outputs of the opto-electronic converter 300 provide electrical inputs of the star coupler 200 represents.

The electrically received signals are at least two outputs 201 - 204 of the electric star coupler 200 placed.

If the optoelectronic transducer is designed as a transmitting transducer, a data transmission takes place in the reverse direction. The at the optical terminal 104 applied optical signals are thereby applied to the terminals 101 . 102 . 103 and the optical fibers connected thereto 401 . 402 . 403 distributed.

In a bidirectional data transmission with a bidirectional optoelectronic converter 300 a data transmission can take place in both directions.

In the illustrated passive optical star coupler 100 it is an N × 1 coupler. Likewise, the star coupler may be formed as an N × M coupler, in which case the coupling region 120 would contain more terminals.

One active electrical star coupler in the sense of the present invention is any electrical coupler that receives the signal of at least one electrical Input distributed to at least one of a plurality of electrical outputs. examples for An electric star coupler is a switch and a router.

In the in the 1 shown star couplers are the multiple input fibers 401 . 402 . 403 on the one coupling side 110 for example, twisted and fused. Such a design of a star coupler is also referred to as a fusion coupler. However, any other embodiments of an optical star coupler can also be used.

For example, the shows 2 a star coupler 100 in which all terminals 101 . 102 . 103 . 104 on the same front 110 are formed. At the other end 150 a reflecting mirror is formed, wherein the light coupled out of one fiber reflects at the mirror and couples into the other fibers. Such star couplers are also referred to as reflective star couplers.

In one embodiment, the body of the star coupler 100 from a diffused glass, resulting in an additional distribution of light in the star coupler 100 leads.

Except for the different design of the star coupler 100 corresponds to the embodiment of 2 the embodiment of the 1 so that for further description and explanation of this embodiment to the comments to 1 is referenced.

In the 1 and 2 is one of the terminals 104 of the optical star coupler 100 with the electric star coupler 200 connected. This terminal 104 that would be used for data transmission with another optical node or terminal without the invention is thus used to stream the data to the electric star coupler 200 provide. The optoelectronic converter 300 , which is required for such a data transmission is doing on or in the electric star coupler 200 realizes and forms in the electric star coupler a gateway to an optical network.

The arrangement of the converter 300 at the electric star coupler 200 allows the optical star coupler 100 completely passive, that is to train without own power supply. In this case, the optical star coupler 100 far away from the electric star coupler 200 be realized, for example, in environments that support an active electric star coupler 200 would be inappropriate, such as a hot environment such as an engine room, a radiant environment or an explosion-proof environment.

The arrangement of the converter 300 at the electric star coupler 200 also causes the symmetry between the individual terminals and associated data channels of the optical star coupler 100 is not disturbed, which has a favorable effect on the distribution of the light power to the individual channels.

The arrangement of the converter 300 at the electric star coupler 200 further allows easy production of the optical star coupler, without the need for the arrangement of the star coupler on a support for providing a power supply and / or for the realization of electrical data lines to the electric star coupler.

The 3 shows an optical network comprising a plurality of fiber optic transceivers (FOT) 601 - 606 via a local optical network with a passive optical star coupler 100 connects with each other. Every fiber optic transceiver 601 - 606 is assigned to a terminal and converts electrical signals of the terminal into optical signals or optical signals to be received by the terminal into electrical signals. On the fiber optic transceivers 601 to 606 is in each case by means of a connector shown schematically as a black rectangle an optical fiber 401 to 406 connected. It is an arbitrary optical fiber, for example a plastic fiber (POF) or a glass fiber (GOF). The fibers 401 to 406 are according to the 1 and 2 with terminals of the passive optical star coupler 100 connected.

One of the terminals of the optical star coupler 100 is over an optical fiber 407 with an opto-electronic converter 330 connected. This has an electrical output, on which an electrical data line 500 connected.

The length of each fiber 401 to 407 For example, it is between 1 and 15 meters. The network is realized for example in a motor vehicle as a photonic LAN with a star topology. The optoelectronic converter 330 provided a gateway to an electrical system. The gateway 330 can, as in the 1 and 2 shown, in an active electric star coupler or even, as with reference to the 5 by way of example, be realized on a passive optical star coupler.

Based on the embodiments of the 1 and 2 has already been described that the converter 300 can be designed as a unidirectional or bidirectional optoelectronic converter. The 4 shows an embodiment in which two opto-electronic converters 310 . 320 are provided, wherein one of these transducers 310 serves as a receiving transducer and converts optical signals into electrical signals and the other of these converters 320 serves as a transmitting transducer and converts electrical signals into optical signals.

In the embodiment of 4 are as well as in the embodiment of 1 and 2 the transducers 310 . 320 at the electric star coupler 200 realized, for example, they are powered by this. Basically, the converters could 310 but also on the optical star coupler 100 be realized, in which case a separate power supply to the optical star coupler 100 would be required.

It will be in the design of the 4 according to the separation of the transmission channel and the receiving channel two terminals 104 . 105 on the optical star coupler via fiber optic cable 404 . 405 with the converters 310 . 320 connected. This embodiment makes it possible in the electric star coupler 200 simply constructed and separate transmitting and receiving units 310 . 320 to realize.

Alternatively, it is possible to use both optical fibers 404 . 405 to use bidirectionally. The respective unused transmitting and receiving channel could be used as a redundant channel in case of failure of the active channel and contribute to increasing the security of data transmission.

It should also be noted that naturally several wavelengths can be transmitted on each channel, in which case the transducers 310 . 320 separately separate and convert the different wavelengths in one embodiment. The one or more electrical terminals of the optoelectronic converter 310 . 320 each provide electrical terminals of the electrical star coupler 200 represents.

That in the 4 described embodiment with two optical fibers 404 . 405 and thus at least two data channels opens the possibility of additional analyzes and measurements. For example, such an arrangement allows a measurement and estimation of the signal travel between the passive and the active star coupler. Furthermore, optical diagnostic functions can be implemented by, for example, irradiating test signals of different intensities into the optical star coupler and respectively receiving power at the individual terminals 101 - 105 is evaluated.

The 5 shows an embodiment in which the optoelectronic transducer 340 (again designed as a transmitting and / or receiving unit) directly on the optical star coupler 100 is arranged. A terminal 104 of the star coupler 100 is via a short fiber optic transmission path 106 with the optoelectronic transducer 340 connected. This is the output side via an electrical cable 500 with one of the terminals 201 of the electric star coupler 200 connected. The fiber optic transmission path 106 can do this in the star coupler 100 be integrated.

In this embodiment, it is necessary that the optical star coupler 100 receives a power supply, which is the operation of the optoelectronic converter 340 allows. It puts that in the passive optical star coupler 100 integrated transducers 340 a gateway to electrical network units.

If the passive star coupler 100 and the active star coupler 200 mounted on a common circuit board is not a separate data cable 500 required. Also in this case can be the power supply of the converter 340 done via the circuit carrier.

The Restricted invention not in their embodiment on the above Embodiments. In particular, there is no limitation of the invention to particular ones Fiber types, data rates, a certain number of channels or certain network topologies.

Claims (21)

Network for data transmission, - at least one electric star coupler ( 200 ), which has several electrical terminals ( 201 - 204 ), and - at least one optical star coupler ( 100 ), which has several optical terminals ( 101 - 105 ), wherein - at least one terminal ( 104 ) of the optical star coupler ( 100 ) via an optoelectronic converter ( 300 . 310 . 320 . 330 . 340 ) with a terminal of the electric star coupler ( 200 ) is coupled. A network according to claim 1, wherein at least one opto-electronic converter ( 300 . 310 . 320 . 330 ) in the electric star coupler ( 200 ) is arranged or integrated in this. A network according to claim 2, wherein a terminal ( 104 ) of the optical star coupler ( 100 ) via an optical waveguide ( 404 ) with the optoelectronic converter ( 300 . 310 . 320 ) connected is. A network according to claim 2 or 3, wherein the power supply of the opto-electronic converter ( 300 . 310 . 320 ) via the electric star coupler ( 200 ) he follows. A network according to any one of claims 2 to 4, wherein the optical star coupler ( 100 ) is arranged in an environment suitable for an electrical star coupler ( 200 ) is unsuitable. A network according to claim 1, wherein at least one opto-electronic converter ( 340 ) at or near the optical star coupler ( 100 ) is arranged. A network according to claim 6, wherein an output of the optoelectronic transducer ( 430 ) via an electrical cable ( 500 ) with a terminal ( 201 ) of the electrical star coupler ( 200 ) connected is. Network according to one of the preceding claims, wherein the optical star coupler ( 100 ) and the electric star coupler ( 200 ) are arranged on a common circuit carrier. Network according to claims 6 and 8, wherein an electrical connection between the opto-electronic converter ( 430 ) and a terminal ( 201 ) of the electrical star coupler ( 200 ) is realized via the circuit carrier. Network according to one of the preceding claims, arranged such that a data transmission between a terminal of the optical star coupler ( 100 ) and a terminal of the electrical star coupler ( 200 ) is bidirectional, wherein the optoelekotronische converter ( 300 . 330 . 340 ) is a bidirectional opto-electronic converter. Network according to one of claims 1 to 10, which is designed such that a data transmission between a terminal of the optical star coupler ( 100 ) and a terminal of the electrical star coupler ( 200 ) unidirectionally, the converter ( 310 . 320 ) is designed as a unidirectional converter. A network according to claim 11, wherein the optical star coupler ( 100 ) two terminals ( 104 . 105 ) and the electric star coupler ( 200 ) have two terminals, each with the interposition of an opto-electronic converter ( 310 . 320 ), wherein one of the connections realizes at least one transmission channel and one of the connections realizes at least one reception channel. Network according to one of the preceding claims, wherein the terminals ( 101 - 103 ) of the optical star coupler ( 100 ), which do not have an opto-electronic converter ( 300 . 310 . 320 . 330 . 340 ) are connected to a terminal of the electric star coupler, each with a terminal associated with a fiber optic transceiver ( 601 - 606 ) or another optical network component. A network according to any one of the preceding claims, wherein all Components of the network are arranged in a motor vehicle. Network according to one of the preceding claims, wherein the optical star coupler ( 100 ) is reflective. A network according to any one of claims 1 to 15, wherein the optical star coupler ( 100 ) is transmissive. Network according to one of the preceding claims, wherein the optical star coupler ( 100 ) is designed as a passive optical component. Optical network for data transmission - optical coupling means ( 100 ) with a plurality of terminals ( 101 - 105 ), - electrical coupling means ( 200 ) with a plurality of terminals ( 201 - 204 ), - at least one terminal ( 104 ) of the optical coupling means ( 100 ) with at least one terminal of the electrical coupling means ( 200 ) via opto-electronic conversion means ( 300 . 310 . 320 . 330 . 340 ) connected is. A network according to claim 18, wherein the opto-electronic conversion means ( 300 . 310 . 320 . 330 . 340 ) near the electrical coupling means ( 200 ) are arranged or integrated in these. A network according to claim 18, wherein the opto-electronic conversion means ( 300 . 310 . 320 . 330 . 340 ) at or near the optical coupling means ( 100 ) are arranged. Method for data transmission between an optical Star coupler and an electric star coupler, comprising: - Provide data at a terminal of an optical star coupler, - Change the optical data provided at this terminal in electrical data, - Provide the converted data at a terminal of the electric star coupler.