DE2905757A1 - Data communication between stations over unidirectional loop - uses optical fibre links between adjacent stations connected together by ring main - Google Patents

Abstract

A number of stations (1, 2, 3) communicate with each other over optical fibre links. The links are connected together to form a complete loop and information passes round it in one direction only. At each station, the incoming fibre is terminated by an optoelectronic transducer and amplifier and the outgoing fibre (5) is driven by another. The two transducers are normally connected together by a switching circuit. Each station monitors all the communications passing round the loop and intercepts those addressed to it. When a station wishes to send messages, it operates its switching circuit to break the loop and connect the outgoing fibre to its own transmitter. The transducers are amplifiers all receive their power supplies from a ring main (4) running in the same conduit as the optical fibre and fed at one of the stations.

Description

Device for the transmission of information between

Stations The invention relates to a device for the transmission ring of information between stations connected to a transmission channel are.

In a known data transmission system, one transmission channel numerous devices connected by a central station for sending or Receiving data lines, address lines and control lines in parallel get lost. Addressing and the exchange of other data require different Transmission cycles that run according to the "hand-shake" process (How does the IEC bus, "by J. Klaus in Electronics", 1975, issue 5, pages 73-78).

Such a transmission system is in industrial use, in particular with large lengths of the transmission channel and numerous connected stations, susceptible to electrical and electromagnetic interference. The invention lies the object of a device for the transmission of information between to develop stations connected to a transmission channel, in the case of electrical and electromagnetic interference on the transmission channel can be avoided.

The object is achieved according to the invention in that the transmission channel formed as a closed loop consisting of several connecting sections is that the ends of two adjacent connecting sections are connected to a station are that the connecting sections consist of optical fibers, the ends of which at the stations are connected to opto-electrical converters, which on the one hand with an input of a station and on the other hand via a switching element and electro-optical Converters are interconnected that the switching elements by a control signal the station with interruption of the connection between the two ends of the connection sections can be switched to a transmission output of the station and that the power supply the converter, which is galvanically separated from the stations, via a parallel to the optical waveguides running connecting line takes place.

With this arrangement, the information is transmitted between the stations transmitted optically. Therefore interference voltages or electromagnetic interference radiation can occur do not affect the signals. The arrangement is particularly suitable for industrial companies with numerous consumers of electrical energy, which are switched on and off more frequently will. Even with greater distances between the stations, the insensitivity remains against electrical or electromagnetic interference.

For the transmission channel, commercially available Fiberglass existing fiber optic cables can be used.

There are no complex optical branching devices at the individual stations with taps required, through which the light is passed on on the one hand in the loop and on the other hand, guided to or picked up by the respective station would have to be.

In the event of a station failure, the assigned switching element is located either in the position bridging the ends of the connecting sections or in it is brought back into this rest position, so that the arrangement by means of the power supply the converter ensures unimpeded transmission between the light guides ending at the station guaranteed. Prevent or impair station malfunctions or shutdowns therefore not the exchange of information between the other stations.

The connecting line preferably consists of two wires.

This arrangement has the advantage that there are no operating currents via ground connections must be routed to the supply unit.

Interference with other electrical devices can thus largely be avoided avoid.

In an expedient embodiment it is provided that in the Transmission pauses the loop over the switching elements is closed and that for the information transmitted between stations a code to distinguish it from the signals occurring when the loop is closed is used. During the breaks in broadcast this arrangement can cause vibrations in the closed loop, which go into a final state in which the signals on an upper or lower Limit level persist. These signals in the transmission pauses are generated by the arrangement not processed.

Another useful embodiment is that at least a station between the ends of the connecting sections one arranged the duration of the transmitted pulses lengthening or shortening device is, and that the loop is closed in the transmission pauses and a pending on it Constant signal with high or low level from the stations as a message the pause in transmission is recognizable. The constant signal can, for example, arise when the amplifiers and converters cause signal delays and DC amplifiers are arranged between the transducers. The one pending on the loop during the pauses in transmission In this arrangement, the signal is used as an information signal that is sent to the stations notifies the non-transferring state. The stations can respond to this signal Submit send requests.

In an advantageous embodiment, at the beginning of the transmission is of the respective station, the switching element can be switched to the transmission input and one Message of the transmission status can be output to the other stations. This arrangement enables the use of stations with equal rights in terms of broadcasting. It can send the station that interrupts the transmission pause by submitting the message.

In another preferred embodiment it is provided that by a station designated for central control tasks during the transmission breaks the associated switching element can be switched to the transmission output and that with a Send request sent by a station the switching element into its ends the bridging position is switched back. In the broadcast breaks can neither oscillate nor an upper one on the loop with this arrangement Limit levels arise. There are therefore no special circuit-technical measures necessary to receive the signals in the transmission breaks from others, for information transfer to distinguish serving signals.

The interruption of the Sc! Ileife is in the transmission pauses by a Central station made. The construction can be done through this the Simplify substations.

Another favorable embodiment is that the last sending station the assigned switching element in its after completion of the transmission Leaves position, and that with a send request sent by another station the switching element into its position jjberbrjjckende the ends of the connecting sections is switched back. With this arrangement, the stations have equal rights.

Preferably, the loop by actuating the associated Switching element interrupting station sent out a test signal sequence and the reception this episode monitored. The proper transmission status of the loop can be With this arrangement, it is easy to determine in the transmission pauses.

The invention is illustrated below with reference to a drawing Embodiment explained in more detail, from which further features and advantages result.

1 shows a block diagram of a device for transmission of information between stations connected to a transmission channel, Fig. 2 is a picture showing details of an arrangement between the ends of two Transmission channel sections that are connected to a station.

Several stations 1,2,3 between which information is transmitted are connected to a transmission channel 4, which is a closed loop can be operated. This loop 4 is made up of individual channel sections 5 together, each laying between two stations 1, 2 and 2, 3 and 3 and 1 are. The channel sections 5 are made of glass fibers Fiber optic cable, ground via which broadband signals with low attenuation are routed.

The ends of the optical waveguides 5 are each connected to an optoelectronic Converter 6 and an electro-optical converter 7 connected. The optoelectrisclen converter 6 generate electrical signals from the incoming optical signals, while the electro-optical converter 7 to convert electrical signals into optical signals.

The opto-electrical converters 6 feed a switching element in each station 8 an amplifier 9. The switching element 8 can be made contactless and has two entrances. The amplifier 9 feeds the first input, while the second Input is connected to a transmission output 10 in the respective station. Every Station 1,2,3 has an input 11 for reception.

The input Ii is connected to the output of the amplifier 9. The output of the switching element feeds a further amplifier 12, which is the electro-optical converter 7 is connected downstream.

The switching elements 8 are controlled from the stations 1, 2, 3.

In the rest position, which is shown in FIG. 1 at stations 2 and 3 is, the switching element connects the two amplifiers 9 and 12 and thus also the both transducers 6 and 7. The stations 1,2,3 always receive the via the optoelectrical Converter and the amplifier 9 incoming signals. If the switching element 8 is a Connection to the transmission output 10, then the incoming signals are not to the Amplifier 12 forwarded. Instead, the respective station, in FIG. 1 the station labeled 1 deliver information to the transmission channel 4 /. At the inputs 11 of the stations 1, 2, 3 are those occurring on the transmission channel Signals regardless of whether the urgent station is transmitting or not.

Two wires t3, 14 run parallel to the optical waveguides 5 electrical connection line 15. The opto-electrical and electro-optical converters 6,7 and the amplifiers 9,12 are connected to the wires 13,14, which are used as supply lines serve for the operating currents of these parts 6,7,9,12. The wires 13, 14 and the optical fibers 5 can be arranged in a common cable sheath 16. A power supply 17 feeds the operating currents in the wires 13,14.

In the transmission pauses, all switching elements can be in their rest positions , the amplifiers 9, 12 being connected to one another. In the closed Loop of the transmission channel 4 may develop vibrations, which can transition into a steady state in which the signals in the transmission channel 4 are high or low.

The high level can only develop if the amplifiers 9, 12 for the processing of direct current are designed.

To the influence of the vibrations and the stationary signals on the Switch off information transmission, the information is encoded e.g. by transmit pulRcode-modulated signals. Electrical or electromagnetic interference Influences do not apply anyway. During transmission channels from electrical conductors The longer the ladder are, the more susceptible they are to interference, this is the case does not apply to the device described above. Therefore, the device can advantageously both at greater distances between stations 1, 2, 3 and in one Environment with loads that generate disruptive electrical and electromagnetic influences can be used. The device is therefore particularly suitable for industrial companies with extensive systems and often switched on and off electrical consumers Energy.

Commercially available glass fibers can be used as the optical waveguide 5 will. Taps on the optical waveguides 5 are not necessary.

The switching element 8 is controlled by a control signal from the respective substation 1,2,3 switched to the position intended for sending. If this control signal fails, then the switching element 8 is in the rest position, in which a connection between the opto-electrical and the electro-optical converter 6, 7 via the amplifier 9 consists.

If one of the stations 1, 2, 3 fails, the signal will be transmitted between the ends of the optical waveguides 5 assigned to the station are not interrupted. It is therefore still possible to switch between the other stations even if stations fail Information is transmitted. In one of the stations 1, 2, 3, as shown in Fig. 2, the amplifier 9 can be connected to the circuit 18, either the pulses circulating on the transmission channel 4 stretch or shorten. At a Expansion occurs in the transmission pauses in the case of steady-state current amplifiers High level signals. If the circuit 18 shortens the pulses, then it arises in the transmission pauses on the transmission channel 4 a signal with a low level. A pulse stretching is already done in many cases by the transducers 6, 7 and the amplifiers 9,12 that process the impulses only with a certain delay. In this In this case, no separate pulse stretching circuit is necessary.

A high or low level signal is received from stations 1,2,3 processed as a message for a pause in transmission. Retriggerable ones are suitable as reporting elements Flip flops. One of the stations 1,2,3 can only send if this message is for the transmission pause is pending. The corresponding station directs the broadcast by actuation its switching element 8, which is applied to the transmission output 10. Then there the station sends a report of the transmission status to the other stations on the transmission channel tz from. Information can be output in the form of a telegram whose first steps the other stations the occupancy of the transmission channel 4 through report the sending station.

A possibility of oscillations in the transmission channel 4 or constant Avoiding signal levels during rest breaks is to use one of the switching elements 8 to a transmission output of a station during the transmission pauses. The transmission channel 4 is no longer closed. Often one of the serves on a transmission channel connected stations as a central station, which have certain control and monitoring functions exercises. It is assumed that in the device shown in Fig. 1, the station 1 is a central station which, as mentioned at the beginning, the other stations for the Send or receive. While the address data and control signals at the above-mentioned arrangement are transmitted on parallel lines, takes place the transmission in the above-explained arrangement is serial, with only one optical waveguide, for example 5 for addresses, data and control signals can be present. In the central station 1 is also the power supply 17.

If one of the other stations wants to send 2, 3, it switches that their associated switching element 8 to the transmission output 10 and reports to the central station the request to occupy the transmission channel. Central station 1 then gives their switching element 8 free, which connects the amplifier 9, 12 with each other in the rest position.

It is also possible to only have equal stations 1,2,3 on the transmission channel 4 to be connected and channel 4 to be separated during the transmission breaks. This is done using reaches the last transmitting station, which their switching element 8 in the connection position with the transmit output and only then controls it to the other position when another station will send a request.

During the transmission breaks, the central station or one of the stations who have equal rights transmit a test signal sequence and monitor its reception. With this measure is it possible to check the state of the transmission channel 4 review.

If there is no test signal sequence, either a station has one Send request indicated by actuating its associated switching element 8 or loop 4 is disturbed. Both heads can be identified by deciphering the Unfold information coming from the substation.

L e r s e i t e

Claims (9)

Patent claims as a device for the transmission of information between stations that are connected to a transmission channel, d u r c 10 it is clear that the transmission channel is one of several Connecting sections existing loop (4) is formed that the ends of two Adjacent connecting sections are connected to a station (1,2,3) that the connecting sections consist of optical fibers (5), the ends of which at the Stations (1,2,3) are connected to opto-electrical converters (6), which on the one hand with one input of a station (1,2,3) and on the other hand via a switching element (8) and electro-optical converters (7) are connected to one another that the switching elements (8) by a control signal from the station interrupting the connection between the two ends of the connecting sections to a transmission output (10) of the station (1,2,3) are switchable and that the power supply of the galvanic from the stations (1,2,3) separate converter (6,7) via a parallel to the optical waveguides (5) running connecting line (t5) takes place. 2. Apparatus according to claim 1, characterized in that between the opto-electrical transducers (6) and the switching element (8) and between them and the electro-optical transducers (7) amplifiers (9,12) are arranged with their supply connections are placed on the connecting line (14). 3. Apparatus according to claim 1 or 2, characterized in that the connecting line (15) consists of two wires (13, 14). 4. Apparatus according to claim 1 or one of the following, characterized in that in the transmission pauses, the loop (4) is closed via the switching elements (8) and that for the information transmitted between stations a code for differentiation of the signals occurring when the loop is closed (lot) is used. 5. Apparatus according to claim 1, 2 or 3, d a d u r c h g e k e n n notices that in at least one station (1,2,3) between the ends of the connecting sections a device which increases or decreases the duration of the transmitted pulses (18) is arranged, and that the loop (4) is closed in the transmission pauses and a steady high or low level signal pending on it can be recognized by the stations (1,2,3) as a message of the pause in transmission. 6. Apparatus according to claim 1 or one of the following, d a d u r c h e k e n n n n e i c h n e t that at the beginning of the transmission from the respective station (1,2,3) the switching element (8) can be switched to the transmission output (10) and a message the transmission status can be output to the other stations. 7. Apparatus according to claim 1, 2 or 3, characterized in that by a station (1) intended for central control tasks during the transmission breaks the associated switching element can be switched to the transmission output (10) and that at a transmission request sent by a station (2,3) the switching element (8) switched back to its position bridging the ends of the connecting sections will. 8. Apparatus according to claim 1, 2 or 3, characterized in that the station that sent last the assigned switching element after the end of the transmission (18) belsisst in its position, and that at one sent from another station Send request the switching element (8) in its the ends of the connecting sections bridging position is switched back. 9. Apparatus according to claim 7 or 8, d a d u r c h g e k e n n z E i c h e t that in the transmission periods of the loop (4) by actuation of the switching element (8) unterbrecllenden station emits a test signal sequence and the reception of this sequence is monitored.