JP5026921B2 - Node device and ring network state change monitoring system using the same - Google Patents

Description

  The present invention relates to a node device that monitors a ring network state (network congestion, node failure, etc.) from a branch network associated with the ring network, and a ring network state change monitoring system using the node device.

In conventional ring network monitoring from a branch network, ring state data (in the ring side area) in the ring side data area in the node equipment of the ring network is used by the arbitration circuit of this node equipment in the ring side data area. The branch network copies the ring state data (in the branch side data area) to the branch line side data area in the node device periodically via the transmission path (between the node and branch line). It was confirmed by polling (periods of several ms to several hundred ms), and the state change was monitored.
Conventionally, status data is acquired by polling from the monitoring side in this way. (See Patent Document 1)

JP-A-8-242229 (pages 6-14, FIG. 1)

  The ring network monitoring in the conventional branch network is configured as described above, and it is necessary to check the state from the terminal. It takes several ms to several hundred ms until it is detected after the state changes. There is a problem that the load on the branch line network (terminal) side increases in order to perform processing.

  The present invention has been made to solve the above-described problems, and is a node device capable of ensuring immediacy and reducing the load on the branch network side when monitoring a ring network state change from the branch network. And it aims at obtaining the ring network state change monitoring system using this.

In the node device according to the present invention, a ring device is a node device that forms a ring network and is connected to a branch network, and a ring side data area that holds ring state data indicating the acquired state of the ring network, the ring side data Branch side data area that holds ring state data copied from the ring state data of the area, previous state holding unit that holds ring state data updated by ring state data held in this branch side data area , this previous state A comparator that compares the ring state data held by the holding unit with the ring state data in the ring side data area, and the ring state data held in the ring side data area are read and passed to the comparator, and also to the comparator An arbitration circuit is provided for instructing the comparison operation. After instructing, confirm that the comparator obtains the ring status data held in the previous state holding unit, the ring status data of the ring-side data area, and copy to branch side data area, the comparator When the comparison results do not match, a state change notification signal is transmitted to the branch network.

As described above, the present invention is a node device that constitutes a ring network and is connected to a branch network, and is a ring-side data area that holds ring state data indicating the acquired state of the ring network. The branch side data area that holds the ring state data copied from the ring state data of the data area, the previous state holding unit that holds the ring state data updated by the ring state data held in the branch side data area, and this previous time A comparator that compares the ring state data held by the state holding unit with the ring state data in the ring side data region , and reads the ring state data held in the ring side data region, passes it to the comparator, and Is provided with an arbitration circuit for instructing the comparison operation, and the arbitration circuit instructs the comparator to perform the comparison operation. Was followed, confirm that the comparator obtains the ring status data held in the previous state holding unit, the ring status data of the ring-side data area, and copy to branch side data area, comparator, compares When the results do not match, the state change notification signal is transmitted to the branch network, so that it is possible to secure immediacy and reduce the load on the branch network side when monitoring the ring network state change from the branch network.

Embodiment 1 FIG.
A first embodiment of the present invention will be described below with reference to FIG.
1 is a block diagram showing a ring network state change monitoring system according to Embodiment 1 of the present invention.
In FIG. 1, each node device 3 constituting the ring network 1 is connected in a ring shape via a transmission line 4, and is connected to a branch network 2 having a terminal 50 via a transmission line 5.
The node device 3 is configured as follows.
Ring state data 13 indicating the state of the ring network 1 such as network congestion or node failure is acquired and stored in the ring side data area 11 by data transmission / reception, and the ring side data area 12 is stored in the ring state data 13. Is stored by the arbitration circuit 10.
The previous state holding unit 15 is connected to the branch line side data area 12 and can read the ring state data 14. The comparator 16 is connected to the previous state holding unit 15 and can read the ring state data held therein.
The arbitration circuit 10 is connected to a comparator 16 in addition to the ring side data area 11 and the branch line side data area 12. As a result, the comparator 16 can read the ring state data 14 via the arbitration circuit 10 and receives the comparison command signal 17 from the arbitration circuit 10 to compare the previous and current ring state data. To make the comparison response signal 18 significant. If they are different, the state change notification signal 20 is considered significant. When the state change notification signal 20 becomes significant, the terminal 50 in the branch line network 2 reads the ring state data 14, confirms that the ring state has changed, and after confirming, makes the state change response signal 21 significant. .

Next, the operation will be described.
The previous state holding unit 15 constantly updates the ring state data 14 in the branch line side data area 12. The arbitration circuit 10 reads the ring state data 13 at a timing when the ring side data 11 is not in use, makes the comparison command signal 17 significant, and passes the current ring state data 13 to the comparator 16.
When the comparison command signal 17 becomes significant, the comparator 16 acquires ring state data held from the previous holding unit 15 as comparison target data. When the acquisition is completed, the comparator 16 makes the comparison response signal 18 significant. The comparator 16 compares the acquired ring state data, and if they are different, makes the state change notification signal 20 significant.
When the arbitration circuit 10 acquires the comparison response signal 18, the arbitration circuit 10 updates the ring state data 14 in the branch line side data area 12 with the ring state data 13.
When the state change notification signal 20 becomes significant, the terminal 50 in the branch line network 2 reads the ring state data 14 in the branch side data area 12 and confirms that the ring state has changed. After the confirmation, the terminal 50 makes the state change response signal 21 significant. Upon receiving the response, the comparator 16 ignores the state change notification signal 20.

  According to Embodiment 1, the above operation allows the terminal to detect a change in the ring state at a high speed and reduce the detection load.

Embodiment 2. FIG.
A second embodiment of the present invention will be described with reference to FIG.
FIG. 2 is a block diagram showing a ring network state change monitoring system according to Embodiment 2 of the present invention.
In FIG. 2, 1 to 5, 10 to 18, 20, 21, and 50 are the same as those in FIG. In FIG. 2, a state change history unit 40 that accumulates a state change history in the node device 3 and a counter unit 41 that counts the number of state changes are provided.

FIG. 3 is a diagram showing an example of history data in the state change history unit of the ring network state change monitoring system according to the second embodiment of the present invention.
In FIG. 3, an end flag bit (1001) is a flag indicating how much data is history data. As shown in the figure, a flag corresponding to the number of ring state data is set to 1. The counter data bit (1002) is the counter state, and the ring state data bit (1003) is the ring state data at the time of the counter. A pair of counter data bit (1002) and ring state data bit (1003) is stored at the storage location address (1000).

Next, the operation will be described.
The previous state holding unit 15 constantly updates the ring state data 14 in the branch line side data area 12. The arbitration circuit 10 reads the ring state data 13 at a timing when the ring side data 11 is not in use, makes the comparison command signal 17 significant, and passes the current ring state data to the comparator 16.
When the comparison command signal 17 becomes significant, the comparator 16 acquires ring state data held from the previous state holding unit 15 as comparison target data. When the acquisition is completed, the comparator 16 makes the comparison response signal 18 significant.
The comparator 16 compares the acquired data, and if they are different, makes the state change notification signal 20 significant. When the arbitration circuit 10 acquires the comparison response signal 18, the arbitration circuit 10 updates the ring state data 14 in the data area 12. The comparator 16 repeats this comparison operation. When the state change response signal 20 is significant and the state change response signal 21 is insignificant, if the comparison result is a state change again, the comparator 16 The ring state data of the previous state holding unit 15 is stored, and at the same time, the counter state is acquired from the counter unit 41 and stored together with the ring state data.

In the example of the data of the state change history unit 40, as shown in FIG. 3, the end flag bit (1001) is a flag indicating how much data is history data. The counter data bit (1002) is the counter state, and the ring state data bit (1003) is the ring state data at the time of the counter.
The operation in this case will be described.
The comparator 16 sets all end flags bit (1001) to 0 when the state change response signal 21 becomes significant. After that, if a state change occurs before the state change response signal 21 becomes significant, the corresponding counter data bit and ring state data bit are written after writing the corresponding bit of the end flag.
When reading, the ring state data corresponding to the flag 1 may be read. Flag 0 indicates a place where ring state data is not stored.
With this end flag, the branch line network 2 can acquire from the history data to the necessary ring state data.

According to the second embodiment, it is possible to efficiently check the history of the ring state change by the above operation, which is effective in monitoring the state trend.

Embodiment 3 FIG.
In the third embodiment, the node device is provided with a function for confirming that the state change logic on the terminal side is operating normally, and the basic operation is the same as that of the first embodiment.
The third embodiment of the present invention will be described below with reference to FIG.
FIG. 4 is a block diagram showing a ring network state change monitoring system according to Embodiment 3 of the present invention.
In FIG. 4, 1 to 5, 10 to 18, 20, 21, and 50 are the same as those in FIG. In FIG. 4, the node device 3 receives a flag change command 43 from the comparator 16 and confirms the state change notification signal 20, and a flag that is started when the state change notification signal 20 is unexpected. A timer 44 (timer) is provided, and branch line state data 45 is stored in the ring-side data area 11. The branch line state data 45 stores a state such as a response error of the terminal 50.

Next, the operation will be described.
The previous state holding unit 15 constantly updates the ring state data 14 in the branch line side data area 12. The arbitration circuit 10 reads the ring state data 13 at a timing when the ring side data 11 is not in use, makes the comparison command signal 17 significant, and passes the current state data to the comparator 16.
When the comparison command signal 17 becomes significant, the comparator 16 acquires the ring state data held by the previous holding unit 15 as comparison target data. When the acquisition is completed, the comparator 16 makes the comparison response signal 18 significant. Then, the acquired two data are compared, and if they are different, the flag changer 43 is instructed to the flag checker 42. The flag checker 42 confirms the state change notification signal 20 when it receives the flag change command 43, and starts the flag timer 44 if it is involuntary, and makes the state change notification signal 20 significant. If the state change notification signal 20 is significant, the state is continued.

When the state change notification signal 20 becomes significant, the terminal 50 reads the ring state data 14 and confirms that the ring state has changed. After confirmation, the branch line network 2 makes the state change response signal 21 significant. When the flag checker 42 confirms that the state change response signal 21 is significant, the flag checker 42 ignores the state change notification signal 20 and initializes the flag timer 44.
When the flag timer 44 exceeds a certain value, it is regarded as a response error of the terminal 50 and the branch line state data 45 is changed. When the terminal 50 is in an abnormal state and the state change response signal 21 cannot be significant, the above operation is performed and a response error occurs.

  According to the third embodiment, the soundness of the terminal 50 can be confirmed on the ring network 1 by the above operation, and the reliability is improved.

Embodiment 4 FIG.
FIG. 5 is a block diagram showing a ring network state change monitoring system according to Embodiment 4 of the present invention.
In FIG. 5, 1 to 5, 10 to 18, 20, 21, and 50 are the same as those in FIG. The configuration in the node device of FIG. 5 is the same as that of FIG. In FIG. 5, a multi-node state change confirmation logic 30 is provided on the terminal 50 so that an abnormal state occurs when a single node changes state by mistake.

FIG. 6 is a flowchart showing the processing of the multiple node state change confirmation logic of the ring network state change monitoring system according to the fourth embodiment of the present invention.

Next, the operation will be described.
On the terminal 50, the multiple node state change confirmation logic 30 connects the transmission paths 5 between the multiple node devices 3 and the branch network 2, the state change notification signal 20, and the state change response signal 21. The multi-node state change confirmation logic 30 can improve reliability by performing redundancy as in the process of FIG. 6 so that a single node changes its state to an abnormal state. It becomes.

Next, the processing of the multiple node state change confirmation logic 30 shown in FIG. 6 will be described.
First, a mismatch counter that is incremented when the state change notification signals of a plurality of nodes do not match is initialized (step 903). The plural node state change confirmation logic 30 confirms whether or not the significant states of the plural state change notification signals 20 match (step 904).
If all the state change notification signals 20 match (step 904) and are significant, it is determined that the state has changed (step 906). If all the state change notification signals 20 do not match (step 904) and they are unintentional, the mismatch counter is incremented (step 907).
While the discrepancy counter is not greater than the specified value (step 908), repeated confirmation is performed (returning to step 904).
When a state change detection abnormality occurs, the node device in which the abnormality is detected is disconnected and excluded from monitoring.

According to the fourth embodiment, erroneous detection can be prevented as described above, and overall reliability can be improved.

It is a block diagram which shows the ring network state change monitoring system by Embodiment 1 of this invention. It is a block diagram which shows the ring network state change monitoring system by Embodiment 2 of this invention. It is a figure which shows the example of the historical data of the state change log | history part of the ring network state change monitoring system by Embodiment 2 of this invention. It is a block diagram which shows the ring network state change monitoring system by Embodiment 3 of this invention. It is a block diagram which shows the ring network state change monitoring system by Embodiment 4 of this invention. It is a flowchart which shows the process of the multiple node state change confirmation logic of the ring network state change monitoring system by Embodiment 4 of this invention.

Explanation of symbols

1 ring network, 2 branch network, 3 node equipment,
4 transmission path (between rings), 5 transmission path (between nodes and branch lines),
10 arbitration circuit, 11 ring side data area, 12 branch line side data area,
13 Ring status data (in the ring side data area),
14 Ring state data (in the branch side data area),
15 previous state holding unit, 16 comparator, 17 comparison command signal, 18 comparison response signal,
20 state change notification signal, 21 state change response signal,
30 multiple node state change confirmation logic, 40 state change history part,
41 counter section, 42 flag checker, 43 flag change command,
44 flag timers, 45 branch line status data, 50 terminals.

Claims (4)

A node device that forms a ring network and is connected to a branch network,
A ring-side data area that holds ring state data indicating the acquired state of the ring network;
Branch line side data area for holding ring state data copied from the ring state data of the ring side data area,
A previous state holding unit for holding ring state data updated by the ring state data held in the branch line side data area ;
A comparator for comparing the ring state data held by the previous state holding unit with the ring state data in the ring-side data region ;
And reading the ring state data held in the ring side data area, passing the data to the comparator, and an arbitration circuit for instructing the comparator to perform a comparison operation,
The arbitration circuit, after instructing the comparator to perform a comparison operation, confirms that the comparator has acquired the ring state data held in the previous state holding unit, and then performs a ring-side data region ring. Copy the status data to the branch line side data area,
A node device characterized in that the comparator transmits a state change notification signal to the branch network when the comparison result does not match.   2. The node device according to claim 1, further comprising a state change history unit that accumulates ring state data when the state changes.   A timer that is started when a state change occurs, and a flag check that initializes the timer by a response from the branch network and considers a response error from the branch network when the timer value exceeds a predetermined value. The node device according to claim 1, further comprising a device.   A plurality of node devices according to any one of claims 1 to 3 and a branch line network connected to the plurality of node devices, wherein the plurality of node devices detect coincidence of state change notification signals from the plurality of node devices. A ring network state change monitoring system comprising: a branch line network having a node state change confirmation logic.

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