DE3801607A1 - Through-connecting device to through-connect the communications channels in the node points of a meshed network - Google Patents

Abstract

The invention relates to a through-connecting device to through-connect the communications channels in the node points of a meshed network in electrical communications systems, the node points being connected by the communications channels. Each node point contains a through-connecting device, a communications transmitter and a communications receiver. The communications transmitters only sporadically transmit any communications, i.e. they are only sporadically active. However, when a communications transmitter transmits, the communication is intended to reach all the communications receivers of the entire network. A meshed network has the advantage here that this is possible even if individual communications channels fail. However, a meshed network requires measures to prevent the formation of feedback loops. Both are achieved by the through-connecting device.

Description

The invention relates to a switching device for Switching through the news channels in the nodes of a mesh network.

Such a switching device is from the German Patent specification 27 53 093 known. It will be in the electrical Telecommunications in every node of a mesh network used, the nodes through news channels are connected.

A section of such a mesh network is shown in FIG. 1. With KN 1 , KN 2 , KN 3 three nodes are designated. You and other nodes, not shown, are interconnected by message channels NK . As indicated by the arrows, the message channels are set up for duplex operation, that is to say they have two opposite transmission directions. Each node contains a switching device DE and a message transmitter NS and a message receiver NE .

The news broadcasters NS only send any messages sporadically, ie they are only sporadically active. However, if a news broadcaster sends, the message should reach all message recipients NE of the entire network. A mesh network has the advantage that this is possible even if individual message channels fail. However, a mesh network requires measures against the formation of feedback loops. Both are brought about by the switching device.

As long as no news transmitter is active, that is to say in the idle state, there are no connections in the switching devices DE between the news channels NK with one another and with the associated news transmitter NS and the associated news receiver NE .

Then if z. B. If the news transmitter NS becomes active in the node KN 1 , it is switched through by the switching device DE there to all the outgoing message channels to the other nodes. As a result, the message channels arriving from node KN 1 become active in nodes KN 2 and KN 3 . With the terms "incoming" and "outgoing message channel", of the two opposite transmission directions of a message channel, the one is referred to that which leaves at one node and arrives or ends at the next node.

At the node KN 2 , this incoming message channel is switched through to the message channels outgoing to the node KN 3 and to the further node, which is no longer shown, and to the message receiver NE in the switching device there. Analogously, the same thing happens in the node KN 3 and in the other nodes that are no longer shown. This means that two incoming message channels can become active in a node. If there are more stitches that are no longer shown here, there may be more than two. However, since only one of the active message channels is switched through to the outgoing message channels, there are no feedback loops.

The reference numerals A 1 , A 2 , A 3 and A 8 and E 1 , E 2 , E 3 and E 8 still entered in FIG. 1 are explained in the description of FIG. 2.

The known switching device is for use in one mesh network formed from analog news channels educated. To transmit such news channels Analog signals, e.g. B. audio frequency signals in the frequency range of 300 Hz to 3400 Hz News broadcasters and news recipients trained. they send or receive the messages in the form of Audio frequency signals.

The invention has for its object a Switching device of the above type to specify Use in one of digital signal message channels formed mesh are suitable. The interfaces such message channels are in the German standard DIN 66 259 Part 2 and Part 3 described.

This object is solved by claim 1.

The invention is illustrated by hand in figures Described embodiments, the following assignment applies:

In Figs. 2, 4 and 5, the through-connect devices are depicted DE itself. Some functions are explained with reference to FIG. 3.

There will first be described FIG. 2. On the left are eight message channel inputs E 1 . . . E 8 shown. Everyone is with an activity detector B1 . . . B 8 and a release switching means FS 1 . . . FS 8 connected. Each activity detector is connected to the associated release switching means via a control line (not shown). The release switching means FS 1 . . . FS 8 are connected to a coupling switching device KS . It has an output which is connected to an end-of-activity detector TE and to all message channel outputs A 1 . . . A 8 is connected. A controller St is also provided, which is connected to the end-of-activity detector TE and the coupling switching means KS .

To explain the function, reference is made once again to FIG. 1. The reference symbols A 1 , A 2 , A 3 and A 8 and E 1 , E 2 , E 3 and E 8 entered there mean the message channel outputs and inputs mentioned above. These inputs and outputs are thus combined in pairs and connected to the individual message channels and the news transmitters NS and message receivers NE .

Further functions are first explained with reference to FIG. 3. The message channels only transmit two different signal states, namely a first and a second signal state. The two signal states are expressed by different voltages U between the relevant signal conductor and the associated reference conductor. The first signal state is expressed by a voltage U ₁ = 0 V and the second signal state by a voltage U ₂ = 5 V.

The first signal state is assigned to the idle state. If a news transmitter NS becomes active, the first signal state changes to the second signal state at its output. This change is also called "occupancy" and is denoted by t ₁ in FIG. 3. This is followed by the so-called advance up to time t ₃ , in which the second signal state persists. After the lead, ie from time t ₃ to time t ₄ , a message is transmitted by changing the two signal states. After time t ₄ , the news transmitter NS is in the idle state and its output again has the first signal state.

A previously described signal consisting of pre-run and message is also referred to as a telegram. If the message transmitter NS sends such a telegram in the node KN 1 , this first arrives at the switching device DE of this node and there at the activity detector B 8 , see FIG. 2. This detects the change of the signal states at time t ₁ ( FIG. 3). . After a certain time delay, he causes the control line (not shown) ( FIG. 2) to enable the release switching means FSB . The message channel connected to the message channel input E 8 is thus released for switching. The time delay ensures that short interference signals do not yet lead to release and connection.

The coupling switching means KS is initially designed as a continuously rotating switch. In a manner not shown it is achieved that this switch remains on an enabled message channel. In the case described here, it remains on the message channel E 8 . This incoming message channel is thus switched through to all outgoing message channels A 1 to A 8 . The time of this switching is designated t ₂ in FIG. 3. Since the coupling switching means KS can only remain on a single released message channel, only one message channel is switched through, even if several are released.

After connection in the node KN 1 , the activity detector B 1 in the node KN 2 and the activity detector B 3 in the node KN 3 detect the change in the signal states, but only after the time t ₂ . The interconnection then takes place in the same way as previously described for the node KN 1 . In this way, the interconnection spreads across the entire network, but the lead time is always shorter by the time delay in the respective activity detector. However, the NS news channels are designed so that they send such a long lead that there is still a sufficiently long lead in the last node.

After the end of the telegram, that is after time t ₄ ( FIG. 3), the connection must be canceled again. This is caused by the end-of-activity detector TE . The end of activity is recognized when the first signal state has continuously lasted longer than an activity end test time. This end of activity test time is longer than the longest possible duration of the first signal state within a telegram. The time at which the end of the activity is recognized is denoted by t ₅ in FIG. 3. The coupling switching means KS is caused to cancel the existing connection via the control unit St.

The time from time t ₅ to time t ₇ is referred to as overrun locking. During this time, the coupling switching means KS is prevented by the controller St from connecting an enabled message channel. The time of the lag lock is divided into a blocking time, which ranges from t ₅ to t ₆ , and a channel test time, which ranges from t ₆ to t ₇ . During the channel check time, all message channels are checked to see if they are idle. After time t ₇ , only those message channels are released for switching which were in the idle state during the channel test time. This measure ensures stable operation even under the circumstances of a mesh network and the fact that the end of a circuit gradually spreads throughout the network, similar to a circuit.

The further development according to claim 2 or FIG. 4 will now be described. In the line from the coupling switching means KS to the message channel outputs A 1 . . . A 8 a regenerator Reg is inserted. This regenerator distributes the edges of the signal state changes and eliminates interference signals. This allows the construction of large networks.

In the development according to claim 3, the regenerator Reg is designed so that it extends the lead by the time delay in the activity detector. The shortening caused by this time delay is therefore canceled again. This allows the construction of large networks regardless of a minimum length of the lead.

Next, the training according to claim 4 and Fig. 5 will be described. To every incoming message channel input E 1 . . . E 8 is a line monitor LÜ 1 . . . LÜ 8 connected. The line monitoring LÜ 1 . . . LÜ 8 are also connected to the controller St. This and the appropriate design of the control system St achieve:

• a) recognition of permanent stations,
• b) Detection of interrupted news channels.

Re a): Due to a defective news transmitter or external interferers, there can be a permanent change between the two signal states or the second signal state on an incoming message channel, which are recognized by the activity detector concerned as occupancy and thus lead to connection. Since the end-of-activity detector never recognizes the end of a telegram in such a case, such a message channel would be continuously switched through. This would block the entire network for meaningful message transmission. To prevent this, each of the line monitors is LÜ 1 . . . LÜ 8 designed so that it detects these faults together with the controller St and disconnects the relevant message channel. After a waiting period, the message channel is checked whether the idle state has occurred. If so, the separation is lifted. If not, a waiting period starts again. These waiting times are initially the same a few times and then increase each time to a maximum. After the waiting time has expired a few times, this is displayed to the staff, who can then finally disconnect the message channel.

Re b): Although a mesh network is still operational after an interruption of individual message channels, such interruptions must be recognized and displayed to the operating personnel. Since an active incoming message channel is switched through to all outgoing message channels, all incoming message channels must become active in all nodes after the switch has spread throughout the network. If one is missing, this is an indication of an interruption. The line monitoring LÜ 1 . . . LÜ 8 , together with the control unit St, recognize such a message channel that has not become active and indicate this to the operating personnel.

The switching device according to the invention is well suited for setting up telecontrol networks. Such telecontrol networks will set up to spatially extended facilities, e.g. B. Energy supply networks and communications networks, to monitor and control remotely.

Claims (4)

1. Switch-through device for switching the message channels in the nodes of a mesh network with the following features:

• a) It has several message channel inputs (E 1 ... E 8 ) and several message channel outputs (A 1 ... A 8 ).
• b) An activity detector (B 1 ... B 8 ) is connected to each message channel input.
• c) Each activity detector (B 1 ... B 8 ) is designed to perform the following functions:
  • c1) Detection of a change from a first to a second signal state on the relevant message channel input (E 1 ... E 8 ).
  • c2) Detect that the second signal state has persisted during a certain time delay. If this is the case, the relevant message channel is recognized as active.
• d) Coupling switching means (KS) are provided which switch through the message channel input recognized as active by the relevant activity detector to all message channel outputs (A 1 ... A 8 ). If several message channel inputs are recognized as active, only one of them is switched through to the message channel outputs.
• e) An activity end detector (TE) is provided, which monitors the switched message channel for the end of the activity. The end of the activity is recognized when the first signal state has persisted continuously during an activity end test time.
• f) A control unit St is provided which, after the end of the activity, causes the coupling switching means KS to cancel the connection.
• g) The control system causes overrun locking. During the period of overrun locking, the coupling switching means KS is prevented from connecting through a message channel recognized as active.
• h) The controller checks all message channels in a channel check time at the end of the lag lock time to determine whether they are in idle status. After the delay lock time, only those message channels are switched through that were in the idle state.

2. switching device according to claim 1, wherein a regenerator (Reg) is inserted between the coupling switching means (KS) and the message channel outputs (A 1 ... A 8 ). This regenerator (Reg) is designed so that the edges of the signal changes are distributed and interference signals are eliminated. 3. switching device according to claim 2, wherein the regenerator (Reg) is designed so that it extends the lead by the time delay in the activity detector. 4. switching device according to claim 1, 2 or 3 with the following features:

• a) A line monitor (LÜ 1 ... LÜ 8 ) is connected to each message channel input (E 1 ... E 8 ).
• b) Every line monitoring LÜ 1 . . . LÜ 8 ) is connected to the control (St) .
• c) The line monitors (LÜ 1 ... LÜ 8 ) and the control unit St are designed so that the following functions are carried out:
  • c1) Detection of a permanent transmitter on a news channel entrance and disconnection of this news channel.
  • c2) Detection of a message channel that has not become active after switching through.