DE3801607C2 - - Google Patents

Description

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

Such a switching device is from the German Publication 31 50 474 known. She will be in the electrical communications technology in each node of a Mesh network used, with the nodes through Message channels are connected.

The following expressions and reference symbols correspond to one another:

P 38 01 607.9 DE-OS 31 50 474 Switching device DE Node 1 D News channels NK Channels CH₁. , , CH₄ News station NS, Terminal 20 Message receiver NE Terminal 20 Node KN 1 . , , KN 3 Node 10 with terminal 20 trailing locking Time Δt

The message channels are set up for duplex operation, d. that is, they have two opposite transmission directions  on. Each node contains a switching device and a news channel and a message recipient.

The news channels only sporadically send any News, d. h., they are only sporadically active. If but a message sender sends the message to everyone Nodes of the whole network get. As long as no News channel is active, ie retired, insist in the Durchschalteeinrichtungen no connections the News channels with each other and with the associated Message sender and the associated message recipient.

If then a news station is active in a node becomes, it is from the local switching device to all going to the other nodes Switched through news channels. In the others Nodes becomes the respective arriving incoming News channel to the outgoing news channels connected through. This is how one gets active Message sender sent message to all nodes.

Because of the formation of the network as a mesh network and because too is switched through to the outgoing message channel, the the originally active incoming news channel is finally assigned to a node further incoming message channels active. The Throughput thus spreads throughout the network.

After the end of an activity is in the respective node the circuit is canceled again. Also this fuss spreads throughout the network. To ensure stable operation of the To ensure network, may in a node a new Switching only take place after the previous one  Switching was completely canceled. To achieve this, it is known to provide a tracking lock.

The invention is based on the following object: It should be a additional measure to ensure a stable Operation can be specified.

This object is achieved by a switching device according to solved according to claim 1.

The subclaims teach advantageous developments.

The invention will be described with reference to FIGS Embodiments described, the following assignment applies:

With reference to FIG. 1, the application of the through-switching device according to the invention will be described. FIGS. 2, 4 and 5 show the switching devices DE themselves. With reference to FIG. 3, some functions will be explained.

First, Fig. 1 will be described. In it a section of a mesh is shown. KN 1 , KN 2 , KN 3 designate three nodes. They and other nodes, not shown, are interconnected by message channels NK. As indicated by the arrows, the message channels are configured for duplexing, ie, they have two opposite directions of transmission. Each node contains a switching device DE and a message transmitter NS and a message receiver NE.

The news channels NS only sporadically send any News, d. h., they are only sporadically active. If but a message sender sends the message to everyone Receive message receiver NE of the whole network. in this connection has a mesh network the advantage that this even in case of failure individual message channels is possible. However requires a meshwork measures against the formation of Feedback loops. Both will be through the Switching device causes.

As long as no news channel is active, ie at rest, exist in the Durchschalteeinrichtungen DE no Links of the news channels NK with each other and with the associated news station NS and the associated Message receiver NE.

If then z. B. a news station NS in the node KN 1 is active, it is turned on by the local switching device DE to all outgoing to the other nodes message channels. As a result, the message channels arriving from the node KN 1 become active in the nodes KN 2 and KN 3 . The terms "incoming" and "outgoing message channel" designate, from the two opposite directions of transmission of a message channel, that which leaves at a node and arrives at the next node.

In node KN 2 , this incoming message channel is switched through to the node KN 3 and to the further node not shown outgoing message channels and to the message receiver NE in the local Durchschalteeinrichtung. Analogously, the same happens in the node KN 3 and in the not shown further nodes. Thus, two incoming message channels can become active in one node. If there are more, not drawn, stitches, there may be more than two. Since only one of the active message channels is switched through to the outgoing message channels, there are no feedback loops.

The in Fig. 1 nor registered reference symbol A 1, A 2, A 3 and A 8, and E 1, E 2, E 3 and E 8 are explained in the description of Fig. 2.

Next, Fig. 2 will be described. On the left are eight message channel inputs E 1 . , , E 8 shown. Each is equipped with an activity detector B 1 . , , B 8 and a release switching means FS 1 . , , FS 8 connected. Each activity detector is connected to the associated enable switching means via an unspecified control line. The release switching means FS 1 . , , FS 8 are connected to a coupling switching means KS. It has an output connected to an activity end detector TE and to all the message channel outputs A 1 . , , A 8 is connected. There is further provided a controller St, which is connected to the activity end detector TE and the coupling switching means KS.

To explain the function, reference is again made to FIG. 1. With the reference numerals A 1 , A 2 , A 3 and A 8 and E 1 , E 2 , E 3 and E 8 entered therein, the aforementioned message channel outputs and inputs are meant. These inputs and outputs are thus combined in pairs and connected to the individual message channels and the news channels NS and message receivers NE.

Further functions will first be explained with reference to FIG. 3. The message channels transmit only two different signal states, namely a first and a second signal state. The two signal states are expressed by different voltages U between the respective signal conductor and the associated reference conductor. The first signal state is expressed by a voltage U₁ = 0 V and the second signal state by a voltage U₂ = 5 V.

The idle state is assigned the first signal state. If a message transmitter NS is active, the first signal state changes to the second signal state at its output. This change is called "assignment" and is denoted in FIG. 3 t _1. It then follows until the time t _3, the so-called flow, in which constantly the second signal state. 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 station NS is in the idle state, and its output again has the first signal state continuously.

A previously described, consisting of flow and message signal is also referred to as a telegram. If the message transmitter NS transmits such a telegram at the node KN 1 , this first reaches the switching device DE of this node and there the activity detector B 8 , see FIG. 2. This recognizes first the change of the signal states at the time t ₁ ( FIG. , After a certain time delay, it causes via the unspecified control line ( Figure 2) that the release switching means FSB turns on. Thus the message channel connected to the message channel input E 8 is enabled for switching through. The time delay ensures that short interference signals do not lead to the release and switching through.

The coupling switching means KS is designed as an initially constantly rotating switch. In a manner not shown ensures that this switch stops on a shared news channel. In the case described here he remains on the news channel E 8 stand. Thus, this incoming message channel is switched through to all outgoing message channels A 1 to A 8 . The time of this connection is indicated in Fig. 3 with t ₂ . Since the coupling switching means KS can remain only on a single shared message channel, only one message channel is switched through, even if several are enabled.

After switching through at 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 of the signal states, but only after the time t ₂ . The switching is then done in the same manner as previously described for the node KN 1 . Thus, the transmission spreads over the entire network, but the lead is always shorter by the time delay in the respective activity detector. However, the news channels NS are designed so that they send such a long lead, so that in the last node still a sufficiently long flow is left.

After the end of the telegram, ie after the time t ₄ ( FIG. 3), the connection must be canceled again. This is effected by the activity end detector TE. The end of activity is considered to be detected when the first signal state has continued uninterruptedly for more than one activity transmission test time. This activity end test time is longer than the longest possible duration of the first signal state within a telegram. The point in time at which the end of the activity is detected is designated t ₅ in FIG. 3. About the control St the coupling switching means KS is caused to cancel the existing switching.

The time from time t ₅ to time t ₇ is referred to as lag lock. During this time, the control circuit St prevents the coupling switching means KS from switching through a shared message channel. The time of the tracking lock is divided into a lock time ranging from t ₅ to t ₆ and a channel test time ranging from t ₆ to t ₇ . During channel test time, all message channels are checked to see if they are idle. After the time t ₇ , only such message channels are enabled for connection, which have been in the idle state during Kanalprüfzeit. This measure also ensures stable operation under the conditions of a mesh network and the fact that the end of a cross-connection similar to a step-through propagates throughout the network.

The development according to the patent claim 3 or the Fig. 4 will now be described. In the line from the coupling switching means KS to the message channel outputs A 1 . , , A 8 is a regenerator Reg inserted. Through this regenerator, the flanks of the signal state changes are steepened and noise is eliminated. This allows the construction of large networks.

In the development according to claim 3 is the Regenerator Reg designed so that it is the flow around the Time delay in the activity detector extended. It will So the shortening caused by this time delay lifted again. This allows the construction of large networks without Consideration for a minimum length of the flow.  

Next, the development according to the patent claim 5 and Fig. 5 will be described. To every incoming message channel input E 1 . , , E 8 is a line supervision LÜ 1 . , , LÜ 8 connected. The line monitoring LÜ 1 . , , LÜ 8 are also connected to the control St. Thereby, and by appropriate design of the control St is achieved:

• a) Recognition of permanent transmitters,
• b) Detecting interrupted message channels.

To a): Due to a defective message transmitter or by external interferers permanently changing between the two signal states or permanently the second signal state can occur on an incoming message channel, which are detected by the relevant activity detector as occupancy and so lead to the connection. Since the activity end detector never detects a telegram end in such a case, such a message channel would be permanently switched through. This would block the entire network for meaningful message transmission. To prevent this, each of the line monitoring LÜ is 1 . , , LÜ 8 is designed so that it detects these disturbances together with the control St and disconnects the relevant message channel. After a waiting period, the message channel is checked whether the idle state has occurred. If yes, the separation is canceled. If not, a waiting period starts again. These waiting times are equal to a few times each time and then extend each time up to a maximum value. After the waiting time has expired a few times, this is displayed to the staff who can then finally disconnect the news channel.

On b): Although a mesh network is still operable after interruption of individual message channels, such interruptions must be detected and displayed to the operator. 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 circuit has propagated throughout the network. If one is missing, this is a sign of an interruption. The line monitoring LÜ 1 . , , LÜ 8 recognize together with the controller St such a message channel has become active and indicate this to the operator.

The switching device according to the invention is well suited for the construction of telecontrol networks. Such telecontrol networks will be set up to accommodate spatially extended facilities, such B. Power grids and telecommunications networks, remotely monitored and remotely controlled.

Claims (6)

1. Durchschalteeinrichtung for switching through 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 function: detection of a change from a first to a second signal state on the respective message channel input (E 1 .. E 8 ). 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 the message channel outputs (A 1, ... A 8 ). If multiple message channel inputs are detected as active, only one of them will be passed through to the message channel outputs.
• e) An activity end detector (TE) is provided, which monitors the switched-through news channel for the end of the activity.
• f) A control St is provided which, after detecting the end of the activity causes the coupling switching means KS to cancel the switching.
• g) The control causes a tracking lock. During the time of the tracking lock, the coupling switching means KS is prevented from switching through a message channel recognized as active.
• h) The controller checks in a channel test time at the end of the time the tracking lock all news channels, whether they are in the idle state. After the time of the tracking lock only those message channels are switched through, which have been in the idle state.

The introductory sentence and the features a) to g) form the Generic term. Feature h) forms the characterizing part. 2. Through-switching device according to claim 1, characterized by the following features:

• a) Each activity detector (B 1 .. B 8 ) is designed to carry out the following function: The relevant message channel is not recognized as active until the second signal state has persisted for a specific time delay.
• b) The activity end detector (TE) is designed to perform the following function: The end of the activity is detected when the first signal state has continued uninterrupted during an activity end test time.

3. Through-switching device according to claim 1 or 2, characterized in that between the coupling switching means (KS) and the message channel outputs (A 1 .. A 8 ), a regenerator (Reg) is inserted. This regenerator (Reg) is designed so that the edges of the signal change steepens and noise can be eliminated. 4. Through-switching device according to claim 3, characterized characterized in that the regenerator (Reg) is designed such that he is the lead around the time delay in the Activity detector extended. 5. Through-switching device according to claim 1, 2, 3 or 4, characterized by the following features:

• a) A line monitoring (LÜ 1 .. LÜ 8 ) is connected to each message channel input (E 1 .. E 8 ).
• b) Each line monitoring LÜ 1 . , , LÜ 8 ) is connected to the control (St).
• c) The line monitoring (LÜ 1 ... LÜ 8 ) and the control St are designed to perform the following functions:
  • c1) Detecting a continuous transmitter on a message channel input and disconnecting this message channel.
  • c2) Detecting a message channel that has not become active after a through connection.