JP4299411B2 - Monitoring control path setting method, monitoring control system, monitoring control apparatus, and communication apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a monitoring control path setting method, a monitoring control system, a monitoring control apparatus, and a communication apparatus in a network in which communication apparatuses such as a plurality of exchanges and data transmission apparatuses are connected to each other.
[0002]
[Prior art]
FIG. 19 is an explanatory diagram of a network, showing a case where a network is configured by connecting nodes 1 to 6 (communication devices such as an exchange) in a mesh shape, NSP is set as a monitoring control device, and SP1 to SP6 are set as transmission paths. The monitored control paths, L1 to L3, indicate transmission paths for which no monitor control path is set. Actually, a larger number of nodes are connected to form a network.
[0003]
The monitoring control device NSP collects status information and the like of the nodes 1 to 6 through the monitoring control paths SP1 to SP6 indicated by double lines, monitors the network, and designates control information from the monitoring control device NSP. To control the network.
[0004]
FIG. 20 is an explanatory diagram of a conventional monitoring control apparatus. The monitoring control apparatus 110 includes a monitoring control IF (interface) unit 111 that communicates with a node, sending monitoring control data to the node, and a collected node. This includes a monitoring control processing unit 112 that performs processing such as status information and a status display unit 113 that displays processing results and the like.
[0005]
FIG. 21 is an explanatory diagram of a conventional node, in which 121 is a monitoring control IF unit, 122 is a monitoring control processing unit, 123 is a monitoring control data input unit, 124 is a monitoring control data output unit, and 125 is an input port and an output port. The monitoring control data relay unit 126 having ports (1) to (N), 126 is a monitoring control data input unit corresponding to transmission paths 1 to (N-1), and 126 is compatible with transmission paths 1 to (N-1). The monitoring control data output part is shown. In addition, although the case where it corresponds to the node 1 to which the supervisory control apparatus (NSP) 110 in FIG. 19 is connected is shown, other nodes also have the same configuration.
[0006]
FIG. 22 is an explanatory diagram of a conventional monitoring control data relay unit, 130 is a multiplexing unit, 131 ₁ ~ 131 _N Is the mask part, 132 ₁ ~ 132 _N Is an input processing unit, 133 is an output processing unit, and 134 is a hardware switch unit. Note that the multiplexing unit 130 corresponding to the lower output ports 1 to N is used. ₁ ~ 130 _N 1 shows a configuration of one multiplexing unit 130 of FIG. ₁ ~ 131 _N Whether or not to mask is set by the hardware switch unit 134.
[0007]
For example, when the inputs from the input ports 1 and 2 are multiplexed and output to the output port 1, the multiplexing unit 130 ₁ Mask part 131 ₁ 131 ₂ Open the other mask part 131 _Three ~ 130 _N Is set in the hardware switch unit 134 so as to be closed. When the monitoring control processing unit 122 is connected to the input ports 1 to (N-1) and the output ports 1 to (N-1) of the monitoring control data relay unit 125, the multiplexing unit 130 is connected. _N Mask part 131 _N Therefore, the hardware switch unit 134 is set so that only the mask process is performed.
[0008]
[Problems to be solved by the invention]
Each node configuring the network and the monitoring control device NSP are connected via a monitoring control path, whereby the monitoring control device NSP can monitor and control each node. For this purpose, the mask unit 131 is included in the hardware switch unit 134 of the multiplexing unit 130 constituting the monitoring control data relay unit 125. ₁ ~ 131 _N In this case, it is necessary to set whether or not to perform mask processing.
[0009]
In this case, when the number of ports is large and the number of nodes is large, there is a problem that the setting work amount of the hardware switch unit 134 is increased and a setting error occurs. For example, in FIG. 19, the monitoring control path SP5 is set between the node 3 and the node 5, and the monitoring control path SP6 is set between the node 3 and the node 6. If a monitoring control path is also set between the nodes, for example, the monitoring control data circulates along the route of node 3 → node 5 → node 6 → node 3. In this case, the node 3 also relays between the node 2 and the monitoring control device NSP, and there is a problem that normal network operation cannot be performed when the monitoring control data propagates to the entire network.
[0010]
Whether or not there is a monitoring control path that circulates the monitoring control data can be determined by collecting the setting data of the hardware switch unit 134 of each node. In such a case, it is difficult to collect setting data due to traffic congestion. Therefore, when a monitoring control path setting error or the like occurs, it is necessary to check the setting data of the hardware switch unit 134 of each node, which causes a problem of enormous work.
An object of the present invention is to centrally manage setting, changing, and the like of a monitoring control path in a monitoring control device.
[0011]
[Means for Solving the Problems]
The monitoring control path setting method of the present invention includes a plurality of communication devices, that is, plural In this method, nodes are connected via a transmission line, and a monitoring control path is set for monitoring each node by the monitoring control device. R See Figure 1 When describing, a plurality of meshes connected via a transmission line Communication device, that is, nodes 1-6 And a monitoring control path setting method in a monitoring control system comprising a monitoring control device (NSP) 10 that monitors each of the nodes 1 to 6, wherein the monitoring control device 10 includes identifiers for a plurality of ports P1 to P5. Between the ports P1 to P5 for each of the nodes 1 to 6, based on the connection information for each of the nodes 1 to 6 that associates the identifiers of the other nodes 1 to 6 connected to the ports P1 to P5. A procedure for creating relay information indicating whether or not monitoring control data is relayed, a procedure for the monitoring control apparatus 10 to send relay information to the nodes 1 to 6, and nodes 1 to 6 A monitoring control data relay unit 25 that sets a relay path for monitoring control data between the ports P1 to P5 by mask setting. In this case, all the relay paths between the ports P1 to P5 are masked and an initial setting procedure for enabling reception of the relay information from the monitoring control apparatus 10 is executed, and then received from the monitoring control apparatus 10 to receive the relay information. A procedure for setting a monitoring control path by setting a mask according to the relay information of the own node held in the holding unit. Is included.
[0012]
In order to transfer the relay information and set the monitoring control path, the relay information is transmitted by designating the nodes in the order according to the logical distance from the monitoring control apparatus 10, or from the monitoring control apparatus 10 to each node. It is possible to send relay information in a batch, extract relay information for the own node, set a relay route by the monitoring control data relay unit 25, and relay the relay information to other nodes. In that case, in order to avoid the double setting process, a setting identifier indicating that the setting has been completed can be provided.
[0013]
In addition, when the communication device, that is, when the number of nodes is increased, or when relay information is lost due to connection change or maintenance, etc., the supervisory control device 10 instructs the initial setting by broadcast communication, and then sequentially sets the nodes according to the logical distance. The relay information can be specified and sent, or the relay information for each node can be sent in a batch, and each node can extract and set the relay information of its own node, and set a new monitoring control path.
[0014]
In addition, when the monitoring control path based on the relay information created in the monitoring control device 10 determines whether or not the circulation state is formed with reference to the connection information, each communication device is set as described above when the circulation state is not formed. Relay information can be sent to Each node checks whether or not the received relay information is normal using a check code or the like, and can set the mask of the monitoring control data relay unit only when it is normal.
[0015]
The supervisory control system of the present invention is a supervisory control system having a supervisory control device 10 that monitors a plurality of communication devices, that is, nodes, connected via a transmission line. A connection information holding unit that holds connection information indicating the mutual connection state of 6, a monitoring control path information holding unit that creates and holds relay information for forming a monitoring control path based on the connection information, and a node 1 to 6 includes a monitoring control processing unit that controls transmission of relay information and collects information from the communication device, and each of the nodes 1 to 6 includes a relay information holding unit that holds relay information of the own node; A monitoring control data relay unit 25 that performs mask setting according to the relay information and sets a relay route between ports, and a monitoring control process that performs mask setting of the monitoring control data relay unit 25 according to a setting instruction from the monitoring control device. Those having a part C.
[0016]
The monitoring control apparatus of the present invention creates a connection information holding unit for holding connection information indicating the mutual connection state of the nodes 1 to 6 and relay information for forming a monitoring control path based on the connection information. The monitoring control path information creation unit, the relay information holding unit that holds the relay information created by the monitoring control path information creation unit, and the relay information corresponding to the nodes 1 to 6 held in the relay information holding unit are And a monitoring control processing unit that performs control of sending to 1 to 6.
[0017]
In addition, the monitoring control device refers to the connection information held in the connection information holding unit, checks the relay information held in the monitoring control path information holding unit, and determines whether or not the monitoring control path forms a circulation route. A monitoring control path check unit for determining Also, a monitoring control path information comparison unit that compares the relay information held in the monitoring control path information holding unit with the relay information collected from each node and determines whether the relay information is normally set in the node is provided. be able to.
[0018]
The communication apparatus of the present invention, that is, the node, relays between ports by a relay information holding unit that holds relay information from the monitoring control device 10 and a mask setting according to the relay information held in the relay information holding unit. A monitoring control data relay unit 25 that forms a route and sets a monitoring control path, and a monitoring control processing unit C that controls the monitoring control data relay unit 25 and the relay information holding unit are provided.
[0019]
Further, the communication device determines whether or not the relay information from the monitoring control device held in the relay information holding unit is normal, and cancels the change of the mask setting of the monitoring control data relay unit 25 when the abnormality is determined. The relay information determination part to be made can be provided. In addition, a setting identifier indicating whether or not the relay information from the monitoring control device has been set in the relay information holding unit and a setting identifier / relay information version number holding unit for holding the version information of the relay information, and receiving the relay information When the setting identifier indicates that the setting has been set, the monitoring control processing unit C performs no processing, holds the relay information received when the setting identifier does not indicate the setting in the relay information holding, and sets the setting identifier to already set. Can be provided.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is an explanatory diagram of a supervisory control system according to an embodiment of the present invention, wherein 1 to 6 are nodes (communication devices constituting a network), 10 is a supervisory control device (NSP) constituted by workstations and the like, P1 P5 is a port, C is a monitoring control processing unit, IF is a monitoring control IF (interface) unit, and 25 is a monitoring control data relay unit. A double line indicates a monitoring control path on the transmission path, and a thin line indicates a transmission path for which no monitoring control path is set.
[0021]
Each of the nodes 1 to 6 includes a monitoring control data relay unit 25 having ports P1 to P5, a monitoring control processing unit C connected to the port P5, and a monitoring control IF unit IF connecting the monitoring control device 10 and the like. Yes. Further, the case where the monitoring control device 10 is connected to the monitoring control IF unit IF of the node 1 is shown, and the monitoring control device 10 is connected to the monitoring control processing unit C of the node 1 even when the nodes 1 to 6 are initially set. Communication becomes possible.
[0022]
The monitoring control device 10 creates connection information based on the mutual connection status of the nodes 1 to 6 and creates relay information corresponding to each node 1 to 6 for forming a monitoring control bus based on the connection information. Then, it is checked whether or not the monitoring control path formed by this relay information is in the circulating state, and when the circulating state is not formed, this relay information is sent to the nodes 1 to 6.
[0023]
Each of the nodes 1 to 6 receives the relay information corresponding to the node, and sets a relay path between ports by the monitoring control data relay unit 25, thereby forming a monitoring control path. In the illustrated configuration, the port P3 of the node 1 and the port P1 of the node 2 are connected, the port P4 of the node 1 and the port P1 of the node 3 are connected, and the monitoring control paths indicated by double lines respectively. And the port P4 of the node 2 and the port P2 of the node 3 are connected by a transmission line indicated by a thin line, the port P3 of the node 2 and the port P1 of the node 4 are connected, and the port P3 of the node 3 and the node Port P1 of node 5, port P4 of node 3 and port P1 of node 6 are connected, a monitoring control path indicated by a double line is set, respectively, port P2 of node 5 and port P4 of node 4 Are connected by a transmission line indicated by a thin line, and the port P4 of the node 5 and the port P2 of the node 6 are connected by a transmission line indicated by a thin line.
[0024]
Therefore, the monitoring control data for the node 6 from the monitoring control device 10 is, for example, the port P4 of the node 1 → the port P1 of the node 3 → the monitoring control data relay unit 25 → the port P4 → the port P1 of the node 6 → the monitoring control data relay unit 25. → Port P5 → Transfer to the supervisory control processing unit C.
[0025]
FIG. 2 is an explanatory diagram of the monitoring control apparatus according to the embodiment of the present invention, showing the configuration of the main part of the monitoring control apparatus (NSP) 10 of FIG. 1, 11 being a monitoring control IF section, 12 being a monitoring control processing section, 13 is a status display unit, 14 is a monitoring control path information comparison unit, 15 is a monitoring control path information creation unit, 16 is a monitoring control path check unit, 17 is a monitoring control path information holding unit, 18 is a connection information holding unit, and 19 is The connection information preparation part is shown.
[0026]
The monitoring control path information creating unit 15 creates relay information corresponding to a node for forming a monitoring control path based on connection information indicating a connection configuration between nodes in the network, and holds the monitoring control path information. Stored in the unit 17. The connection information creating unit 19 creates the above-described connection information indicating the connection configuration between the nodes and stores it in the connection information holding unit 18.
[0027]
The monitoring control path check unit 16 also relays information based on the relay information corresponding to each node held in the monitoring control path information holding unit 17 and the connection information corresponding to each node held in the connection information holding unit 18. It is checked whether or not the monitoring control path formed by the above is in the circulation state. The check result is notified to the monitoring control processing unit 12. The monitoring control processing unit 12 sends relay information that does not generate a circulation state to the node via the monitoring control IF unit 11.
[0028]
The status display unit 13 displays various processing results by the monitoring control processing unit 12. In addition, the status information of each node is collected and displayed. Alternatively, the relay information held in the monitoring control path information holding unit 17 and the connection information held in the connection information holding unit 18 can be displayed under the control of the monitoring control processing unit 12. The monitoring control processing unit 12 reads the relay information, sends it to the node via the monitoring control IF unit 11, collects the relay information set in the node via the monitoring control IF unit 11, and monitors the monitoring control path information. The relay information held in the holding unit 17 and the collected relay information are compared in the monitoring control path information comparing unit 14 and the comparison result is transferred to the monitoring control processing unit 12. Further, the status information of the node is displayed on the status display unit 13 from the monitoring control processing unit 12.
[0029]
FIG. 3 is an explanatory diagram of a node according to an embodiment of the present invention, showing a communication device such as an exchange, a data transmission device, etc. constituting the network, that is, the main configuration of the nodes 1 to 6 in FIG. Control IF unit, 22 is a monitoring control processing unit, 23 is a monitoring control data input unit, 24 is a monitoring control data output unit, 25 is a monitoring control data relay unit, 25a is a mask setting unit, 26 is a transmission line 1 to (N− 1) A corresponding monitoring control data input unit, 27 is a monitoring control data output unit corresponding to transmission paths 1 to (N-1), 28 is a relay information holding unit, and 29 is a setting identifier / relay information version holding unit.
[0030]
The ports (1) to (N-1) of the monitoring control data relay unit 25 correspond to the ports P1 to P4 in FIG. 1, the port (N) corresponds to the port P5 in FIG. 1, and the monitoring control processing unit 22 is illustrated. 1 corresponding to the monitoring control processing unit C. Therefore, FIG. 3 corresponds to the node 1 of FIG. 1 and shows a case where the monitoring control device (NSP) 10 is connected to the monitoring control IF unit 21 of this node.
[0031]
The relay information holding unit 28 holds relay information indicating the relay route of the monitoring control data from the monitoring control device 10, and based on this relay information, the monitoring control processing unit 22 performs the monitoring control data relay unit 25. The mask unit 25a is controlled. That is, by setting the relay information corresponding to each node from the monitoring control device 10, it is possible to set the mask in the mask unit 25a of the monitoring control data relay unit 25 of each node.
[0032]
The setting identifier / relay information version number holding unit 29 holds a setting identifier indicating whether or not the relay information has been set when the mask is set, and the version number of the relay information based on the relay identifier in that case. The monitoring control processing unit 22 compares the version number of the relay information received from the monitoring control device with the version number of the relay information that is held, and if the version number is the same, it is already held in the relay information holding unit 28. Can be determined. Further, as will be described later, it is possible to easily determine whether or not the relay information has already been set based on the setting identifier.
[0033]
FIG. 4 is an explanatory diagram of the monitoring control data relay unit according to the embodiment of the present invention, showing the main configuration of the monitoring control data relay unit 25 of FIGS. 1 and 3, each corresponding to the lower output ports 1 to N. Multiplexer 30 having the same configuration ₁ ~ 30 _N One of them is shown as a multiplexing unit 30 at the top. The multiplexing unit 30 includes a mask unit 31 corresponding to the input ports 1 to N. ₁ ~ 31 _N And the input processing unit 32 ₁ ~ 32 _N And an output processing unit 33 for multiplexing and outputting, and a mask setting unit 34 (corresponding to the mask setting unit 25a in FIG. 3). Reference numeral 22 denotes a monitoring control processing unit, 28 denotes a relay information holding unit, and 35 denotes a relay information determination unit.
[0034]
The monitoring control processing unit 22 and the monitoring control data relay unit 25 are connected via the monitoring control data input unit 23 and the monitoring control data output unit 24 in FIG. The illustration of these is omitted. Further, a relay information determination unit 35 is provided between the relay information holding unit 28 and the monitoring control data relay unit 25.
[0035]
The mask part 31 corresponding to the input ports 1 to N ₁ ~ 31 _N Information is set in the mask setting unit 34. This setting is performed by the monitoring control processing unit 22 based on the relay information from the monitoring control device as described above. When relaying the monitoring control data between 1 and the output port 1, the multiplexing unit 30 ₁ Mask part 31 ₁ By performing mask setting on the other mask parts except for the input port 1 to the mask part 31 ₁ , Input processing unit 32 ₁ , Output to the output port 1 via the output processing unit 33. When relaying the monitoring control data between the input ports 1 and 2 and the output port 2, the multiplexing unit 30 ₂ Mask part 31 ₁ , 31 ₂ Mask setting is performed for other mask portions except for. As a result, the multiplexer 30 from the input ports 1 and 2 ₂ Mask part 31 ₁ , 31 ₂ And the input processing unit 32 ₁ , 32 ₂ Are multiplexed via the output processing unit 33 and output to the output port 2.
[0036]
When the mask setting unit 34 performs mask setting based on the relay information, the relay information determination unit 35 checks using a check code added to the relay information and sends the check result to the mask setting unit 34. Notice. If normal, mask setting is performed in the mask setting unit 34 based on the relay information held in the relay information holding unit 28. In the case of abnormality, the mask setting unit 34 does not perform mask setting based on this relay information. In addition, the monitoring control processing unit 22 is notified, the monitoring control processing unit 22 notifies the monitoring control device that the relay information is abnormal, and the monitoring control device performs control to reset the relay information. Thereby, an erroneous setting can be prevented.
[0037]
FIG. 5 is an explanatory diagram of the monitoring control path information, showing an example of the monitoring control path information held in the monitoring control path information holding unit 17 of the monitoring control apparatus 10, and corresponds to the number of management nodes M and nodes 1 to M. Each relay information includes a node number, a relay information identifier (version number), a port number, and the presence or absence of connection between the ports corresponding to the input ports 1 to N.
[0038]
FIG. 6 is an explanatory diagram of connection information, showing an example of connection information held in the connection information holding unit 18 of the monitoring control device 10, and a node number where the logical distance from the NSP is 0, that is, the monitoring control device. It includes a node number to which the NSP is connected, the number of management nodes, and connection information corresponding to the nodes 1 to M. Each connection information is connected to the input side corresponding to the node number, the number of ports, and the ports 1 to N. It shows the node number and the node number connected to the output side.
[0039]
For example, in the supervisory control system shown in FIG. 1, the nodes whose logical distance from the supervisory control device 10 is 0 are nodes 1, and the nodes whose logical distance is 1 are nodes 2 and 3. In the case of the nodes 1 to 6, the management node number M = 6. The connection information of the node 1 is information that the node 2 is connected to the port P3 and the node 3 is connected to the port P4. The connection information of the node 3 is information indicating that the node 1 is connected to the port P1, the node 2 is connected to the port P2, the node 5 is connected to the port P3, and the node 6 is connected to the port P4.
[0040]
FIG. 7 is an explanatory diagram of the initial setting of the nodes. As shown in FIG. 7A, the monitoring control data relay unit 25 is connected to the ports 1 to 4 by the control of the initial setting from the system startup or from the monitoring control device. Only the port 5 is connected, and the monitoring control processing unit 22 connected to the port 5 can communicate with any port. As shown in FIG. Between 4 and 4, it is assumed that communication is not possible as indicated by a cross.
[0041]
For example, in FIG. 4, if the port to which the monitoring control processing unit 22 is connected is the output port 5, the multiplexing unit 30. _Five Mask part 31 ₁ ~ 31 _Five Is set in the mask setting unit 34 so as not to mask the input ports 1 to 5, and the multiplexing unit 30 corresponding to the other output ports 1 to 4 is set. ₁ ~ 30 _Four Mask part 31 ₁ ~ 31 _Five The mask unit 31 corresponding to the input port 5 to which the monitoring control processing unit 22 is connected. _Five Only the mask part 31 is not masked. ₁ ~ 31 _Four Is set to mask.
[0042]
Therefore, as shown by the solid line arrow in (A), the port P5 to which the supervisory control processing unit 22 is connected and the other ports P1 to P4 can communicate with each other, but the ports P1 to P4 can communicate with each other. Is in a state where communication is impossible as indicated by a dotted arrow and a cross in (B).
[0043]
FIG. 8 is an explanatory diagram of a monitoring control path setting procedure, and FIG. 8A shows a state in which a monitoring control path is set with the node 1 having a logical distance 0 from the monitoring control apparatus NSP. That is, as shown in FIG. 1, the monitoring control device NSP and the node 1 are connected to the monitoring control processing unit C via the monitoring control IF unit, and the monitoring control processing unit C and the monitoring control data relay unit 25 are connected to each other. Connected to the port P5, the supervisory control data from the supervisory control device NSP is transferred to the node 1. Therefore, when relay information is sent from the monitoring control device NSP to the node 1 to set the monitoring control path, the node 1 can relay the relay information from the monitoring control device NSP to the nodes 2 and 3. It becomes. The other nodes 2 to 6 are initially set as described with reference to FIG.
[0044]
FIG. 8B shows a state where a supervisory control path up to a logical distance 1 from the supervisory control device NSP is set. That is, the monitoring control path is set between the node 1 and the node 2 and between the node 1 and the node 3. In this state, node 2 is in a state where relay information can be relayed and sent to node 4, and node 3 is in a state where relay information can be relayed and sent to nodes 5 and 6. (C) shows a state in which a supervisory control path from the supervisory controller NSP to the logical distance 2 is set. That is, the monitoring control path is set between the node 1 and the node 4 and between the node 3 and the nodes 5 and 6, respectively.
[0045]
FIG. 9 is an explanatory diagram of the setting sequence according to the logical distance, showing the setting sequence of the monitoring control path for the monitoring control device NSP and the nodes 1, 2, 3,... The illustration is omitted to avoid conversion. The nodes 1, 2, 3,... 6 perform the initial setting described with reference to FIG. That is, the nodes 1 to 6 do not perform relay transmission, but the information input to the ports can be received by the respective monitoring control processing units 22.
[0046]
The monitoring control device NSP reads the node number of the logical distance 0 after creating the monitoring control path information and the connection information. The supervisory control path information creation is supervisory control path information from the supervisory control device NSP via each node, created by the supervisory control path information creation unit 15 in FIG. 2 and held in the supervisory control path information holding unit 17. To do. The connection information creation is information indicating the connection between the nodes of the network, and is created by the connection information creation unit 19 and held in the connection information holding unit 18.
[0047]
In that case, a node is assigned a number, and based on the connection information indicating the connection between the nodes, the node to which the supervisory control device NSP is directly connected is set to the logical distance 0, and the node connected to this node is set to the logical distance. In order to set the distance 1, the logical distance indicating the connection order to the monitoring control device NSP and the node number can be associated with each other and held in the connection information holding unit 18. For example, the nodes 1 to 6 are set as node numbers 1 to 6, and the logical distance 0 = node number 1, logical distance 1 = node numbers 2 and 3, and logical distance 2 = node numbers 4, 5, and 6 can be set. it can.
[0048]
Then, the monitoring control path check unit 16 refers to the connection information held in the connection information holding unit 18, and the monitoring control path based on the relay information held in the monitoring control path information holding unit 17 causes data circulation or the like. It is checked whether or not it is not present, and the check result is notified to the monitoring control processing unit 12. The monitoring control processing unit 12 enables transmission of relay information corresponding to the monitoring control path when the check result indicates normality.
[0049]
Then, the node number of logical distance 0 is read and a setting instruction is sent out. As described above, when the logical distance and the node number are stored in association with each other, the number of the node 1 with the logical distance 0 is read out. Then, relay information of the node 1 according to the monitoring control path information is transmitted, and a setting instruction is given. This relay information includes a destination by a node number and the like, information indicating a setting instruction, and the like.
[0050]
In the node 1, referring to FIG. 3, the relay information from the monitoring control device NSP is transferred from the monitoring control IF unit 21 to the monitoring control processing unit 22. The monitoring control processing unit 22 determines that the relay information is addressed to the own node based on the destination node number and the like, and stores the relay information in the relay information holding unit 28. Then, a setting request is sent from the monitoring control processing unit 22 to the mask setting unit 25 a of the monitoring control data relay unit 25. The mask setting unit 25a performs mask setting for the mask unit of the multiplexing unit according to the relay information. Upon completion of this setting, the monitoring control processing unit 22 sends a setting completion notification to the monitoring control apparatus NSP.
[0051]
In this case, the node 1 relays the monitoring control data through the path between the port P5, the port P3, and the port P4, and the initial setting state, that is, as shown in FIG. Since nodes are not connected to ports P1 and P2 in the path between ports P1 to P4, masks are set for ports P1 and P2 as they are, and the mask between ports P3 and P4 is released. Will do.
[0052]
The supervisory control device NSP reads the node number of the next logical distance 1 in response to the setting completion notification from the node 1 of the logical distance 0, and issues a setting instruction. For example, the relay information for the node 2 with the logical distance 1 and number 2 is transmitted to give a setting instruction. The node 2 identifies the relay information addressed to itself as described above, holds the relay information in the relay information holding unit 28, and sets the mask according to the relay information in the mask unit 25a of the monitoring control data relay unit 25. Then, the setting completion notification is sent to the monitoring control device NSP. The monitoring control device NSP transmits relay information to the node 3 and issues a setting instruction. Similarly, the node 3 receives and holds the relay information addressed to itself, and sets the mask in the mask unit 25a of the monitoring control data relay unit 25. Then, the setting completion notification is sent to the monitoring control device NSP.
[0053]
When the monitoring control device NSP finishes sending the relay information to the node of the logical distance 1 and receives the setting completion notification, it reads the node number of the next logical distance 2 and sequentially designates the nodes as described above. The relay information is transmitted to give a setting instruction, and the relay information is transmitted to the next node and the setting instruction is sequentially performed in response to the setting completion notification from the node.
[0054]
When the monitoring control apparatus NSP receives the notification of the completion of setting from the final node 6, the monitoring control apparatus NSP determines that the setting is complete and collects information by broadcast communication. Thereby, each node transmits the relay information of the own node held in the relay information holding unit 28 under the control of the monitoring control processing unit 22. The monitoring control device NSP transfers the collected relay information to the monitoring control path information comparison unit 14, compares it with the node-corresponding relay information held in the monitoring control path information holding unit 17, and compares the comparison result with the monitoring control processing unit. 12 for transfer. If the comparison matches, the process ends normally. A reset operation is performed for nodes that do not match. In this way, relay information for relaying the monitoring control data from the monitoring control apparatus NSP to each node can be set.
[0055]
FIG. 10 is an explanatory diagram of a setting sequence by collective transmission, showing the monitoring control device NSP and the nodes 1, 2, 3, 4,... 6, creating monitoring control path information of the monitoring control device NSP, and nodes 1-6. The initial activation is the same as that shown in FIG. Then, the relay information corresponding to each of the nodes 1 to 6 is designated by the node number, etc., and sent to the node 1 from the supervisory control device NSP in a lump to give a setting instruction.
[0056]
The setting instruction in this case is a state in which each of the nodes 1 to 6 is in an initialized state and does not have a relay function, so that the monitoring control processing unit 22 of only the node 1 is in a receivable state. The relay information is received and held, and the monitoring control processing unit 22 extracts the relay information addressed to the own node 1 and holds it in the relay information holding unit 28. Based on this relay information, the masking unit of the monitoring control data relay unit 25 The mask is set to 25a, and the setting identifier of the setting identifier / relay information version number holding unit 29 is set. Accordingly, since the relay route is set in the monitoring data relay unit 25, the monitoring control processing unit 22 sends the stored batch relay information to the next via the relay route formed in the monitoring control data relay unit 25. Send to node. In this case, the data is transmitted from the port P3 of the node 1 to the node 2 and from the port P5 to the node 3.
[0057]
The nodes 2 and 3 can be received by the monitoring control processing unit 22 and no relay route is set, but the monitoring control processing unit 22 can receive the reception information of any port. The relay information addressed to the own node is extracted and held in the relay information holding unit 28, mask setting is performed, and the setting identifier is set. By setting the relay information, the nodes 2 and 3 form a relay route in the monitoring control data relay unit 25, and therefore relay the collective relay information via the relay route. In this case, node 2 sends relay information to nodes 1, 3, and 4, and node 3 sends relay information to nodes 1, 2, 5, and 6, respectively.
[0058]
When the node 1 receives the collective relay information from the nodes 2 and 3, since the setting identifier has already been set for the relay information addressed to itself, the node 1 does not perform any processing. The node 4 receives the relay information from the node 2, extracts and holds the relay information addressed to itself, sets the mask, sets the setting identifier, and the nodes 5 and 6 receive the relay information from the node 3. The relay information is received, the relay information addressed to the own node is extracted and held, the mask is set, and the setting identifier is set.
[0059]
Next, the batch relay information is transmitted from the nodes 4, 5, and 6, respectively. In this case, the collective relay information is transferred from the node 4 to the nodes 1 to 3, 5 and 6, from the node 5 to the nodes 1 to 4 and 6, and from the node 6 to the nodes 1 to 5, respectively. Each of the nodes 1 to 6 receives the collective relay information, but since the setting identifier indicates that the setting has been completed, no processing is performed.
[0060]
The monitoring control apparatus NSP issues an information collection instruction, for example, a predetermined time after sending the setting instruction. On the other hand, each of the nodes 1 to 6 sends the relay information of the own node held in the relay information holding unit 28 to the monitoring control device NSP. The monitoring control device NSP transfers the collected relay information to the monitoring control path information comparison unit 14, compares it with the node-corresponding relay information held in the monitoring control path information holding unit 17, and compares the comparison result with the monitoring control processing unit. 12 for transfer. If the comparison matches, the process ends normally. For nodes that do not match, the node is designated and relay information is reset. The setting of the monitoring control path by the collective relay information only sends the relay information of all the nodes once, so that the processing of the monitoring control device NSP is simplified.
[0061]
FIG. 11 is an explanatory diagram of the monitoring control path setting. FIG. 11A shows the network configuration shown in FIG. 1, but a monitoring control bus indicated by a double line is set between the node 3 and the nodes 5 and 6. Indicates no state. For example, the relay control changes or disappears due to the exchange of the package at the node 3 for maintenance or the like, and the monitoring control path between the node 3 and the nodes 5 and 6 is set. The case where there is no state is shown. Therefore, this is a case in which the relay information of the node 3 held in the monitoring control path information holding unit 17 of the monitoring control device NSP does not match.
[0062]
The supervisory control device NSP can identify such a state by notification from the node 3 or periodic collection and comparison of relay information from the nodes 1 to 6. In that case, the monitoring control device NSP confirms the node that does not match the relay information, resets the relay information for the node, and between the node 3 and the nodes 5 and 6 as shown in FIG. A monitoring control path indicated by a double line can be set.
[0063]
FIG. 12 is an explanatory diagram of a monitoring control path setting sequence. The monitoring control device NSP and the nodes 1 to 6 are already in operation, and maintenance replacement has been performed in the node 3, so that (B ) From the state of the supervisory control path (A) to the supervisory control path (A). When the supervisory control device NSP identifies this state as described above, it collects information. That is, the relay information of each node 1-6 is collected.
[0064]
Then, the monitoring control device NSP in the monitoring control path information comparison unit 14 performs node processing on the collected relay information transferred from the monitoring control processing unit 12 and the relay information held in the monitoring control path information holding unit 17. Compare to correspondence. In this case, the mismatch of the relay information of the node 3 is detected.
[0065]
Then, the relay information of the node 3 held in the monitoring control path information holding unit 17 is sent to the node 3 and a setting instruction is given. The node 3 receives this relay information, holds it in the relay information holding unit 28, sets the mask in the mask setting unit 25a, and sends a completion notification to the monitoring control device NSP.
[0066]
The monitoring control device NSP collects information again according to the collection instruction. Then, the relay information collected from each of the nodes 1 to 6 and the relay information held in the monitoring control path information holding unit 17 are compared in the monitoring control path information comparison unit 14, and if the comparison matches, the relay information is normal. As confirmation, the monitoring control path setting process is terminated.
[0067]
13A and 13B are explanatory diagrams of node addition. FIG. 13A shows the case where the node 7 is added between the node 3 and the node 6, and FIG. 13B shows the relationship between the node 3 and the node 6 via the node 7. A state in which a monitoring control path is set in between is shown. In this case, the monitoring control path is set between the node 3 and the node 7 by connecting the node 7 to the port to which the node 6 was connected. However, since no relay information is set for the node 7, no monitoring control path is set between the node 7 and the node 6. Therefore, the relay information is set from the monitoring control device NSP to the node 7 and the monitoring control path to the node 6 is set as shown in (B).
[0068]
FIG. 14 is an explanatory diagram of a setting sequence at the time of adding a node. The monitoring control device NSP and the nodes 1 to 6 are in operation. The node 7 is newly added and initially started, and each port of the node 7 and monitoring control processing The mask initial setting of the mask unit 25a of the monitoring control data relay unit 25 is performed so that transmission / reception with the unit can be performed.
[0069]
The monitoring control device NSP detects the inability to communicate with the node 6 based on the information on the addition of the node 7 or the regular communication with the nodes 1 to 6, and also provides connection information on the addition of the node 7. The monitoring control path information is created, and the relay information at the node 7 is transmitted to give a setting instruction. The node 7 receives this relay information, holds it in the relay information holding unit 28, sets the mask in the mask setting unit 25a, and sends a completion notification to the monitoring control device NSP.
[0070]
When the monitoring control device NSP receives the setting completion notification, it sends a collection instruction by broadcast communication, and relay information collected from each of the nodes 1 to 7 and relay information held in the monitoring control path information holding unit 17 Are compared by the monitoring control path information comparison unit 14, and when the comparison coincides with the normality confirmation, the monitoring control path setting process ends. That is, as shown in FIG. 13A, when the node 7 is added between the nodes 3 and 6, the monitoring control path shown in FIG. Can be set. Therefore, even when an additional node is connected to each node, the monitoring control path can be set in the same manner.
[0071]
FIG. 15 is an explanatory diagram of the monitoring control path change. (A) shows the setting state of the monitoring control path shown in FIGS. 1, 8 (C) and 11 (B), respectively. The monitoring control path between the nodes 3 and 6 is changed between the nodes 5 and 6.
[0072]
FIG. 16 is an explanatory diagram of the sequence of setting change by broadcast communication. The monitoring control device NSP and the nodes 1 to 6 are in operation while the monitoring control path is set as shown in FIG. When the monitoring control path for the node 6 is changed from the node 3 to the node 5, the monitoring control apparatus NSP creates monitoring control path information based on the connection information, and broadcasts new relay information corresponding to the nodes 1 to 6 Send out by communication and give setting instructions. Each of the nodes 1 to 6 relays and transmits via the already formed monitoring control path, extracts the relay information of its own node, holds it in the relay information holding unit 28, and masks the monitoring control data relay unit 25 The mask of the unit 25a is set.
[0073]
Then, the monitoring control device NSP issues an information collection instruction after a predetermined time has elapsed from the setting completion notification or setting instruction from each of the nodes 1 to 6, collects relay information from each of the nodes 1 to 6, and collects each node 1 6 is compared with the relay information held in the monitoring control path information holding unit 17 in the monitoring control path information comparison unit 14, and in the case of a comparison match, the monitoring control is performed as normal confirmation. The path setting process ends. As described above, the monitoring control path can be changed all at once by broadcast communication of relay information from the monitoring control device NSP.
[0074]
In this case, each of the nodes 1 to 6 compares the relay information of the received node extracted and the relay information held in the relay information holding unit 28 in the monitoring control processing unit 22, and in the case of a comparison match. The mask setting can be left as it was last time. Alternatively, when the relay information is the same as the previous one, the relay information version number is the same, so the relay information version number held in the setting identifier / relay information version number holding unit 29 and the current broadcast communication are received. The monitoring control processing unit 22 compares the version number of the relay information, and if the version number is the same, the setting change process can be terminated.
[0075]
In FIG. 10, the relay information for each of the nodes 1 to 6 is sent from the supervisory control device NSP in a lump, and each of the nodes 1 to 6 sets and broadcasts the relay information through processing by the supervisory control processor. In this case, the relay information is set in the nodes in the order according to the logical distance, and the processing of the monitoring control device NSP is relatively simple. On the other hand, in FIG. 16, the monitoring control device NSP sends out the relay information of the setting change of each of the nodes 1 to 6 by broadcast communication, and each of the nodes 1 to 6 is already in operation. The relay transmission is performed by the relay route, and the relay information addressed to the own node is extracted and the setting is changed, and the relay information can be set in a short time by broadcast communication when the relay route is set. There is.
[0076]
FIG. 17 is an explanatory diagram of the sequence of setting change by sequential setting instructions. As described above, the monitoring control path is changed while the monitoring control apparatus NSP and the nodes 1, 2, 3,... In addition, monitoring control path information is created based on the connection information, and initialization is instructed to each of the nodes 1 to 6 by broadcast communication. Each of the nodes 1 to 6 performs mask setting with the relay information holding unit 28 as an initial state. That is, as shown in FIG. 7, each of the nodes 1 to 6 sets a state in which communication is possible only between the port P5 to which the monitoring control processing unit 22 is connected and the other ports P1 to P4. Therefore, each node 1-6 will be in the state which does not relay monitoring control data.
[0077]
Next, the monitoring control device NSP creates connection information, reads the node number of the logical distance 0, sends relay information to the node 1 of the logical distance 0, and issues a setting instruction. The node 1 holds the received relay information in the relay information holding unit 28 under the control of the monitoring control processing unit 22 and sets the mask in the mask setting unit 25 a of the monitoring control data relay unit 25. Then, a mask setting completion notice is sent to the supervisory controller NSP.
[0078]
The supervisory control device NSP reads out the node number of the logical distance 1 in response to the completion notification from the node of the logical distance 0, and sequentially sends relay information to the nodes 2 and 3 of the logical distance 1 to instruct setting. Node 1 relays and transmits relay information for node 2 or 3 according to the previously set relay route. Then, similar to the setting sequence according to the logical distance shown in FIG. 9, when transmission of relay information to each node is completed and a setting completion notification is received, the relay information of each node is collected and compared, and the comparison matches If it is
[0079]
FIG. 18 is an explanatory diagram for checking data circulation, and shows an example of connection information and relay information of the nodes 1, 2, and 3. The connection information indicates a node connected to the port, and the relay information indicates whether to relay between ports. For example, as connection information of node 1, port 3 connection node is node 2, port 4 connection node is node 3, relay information indicates a relay between ports 3 and 3, and port 2 connection information is connection information of node 2. The node is node 1, the connection node of port 4 is node 3, relay information indicates relay between ports 1 and 4, and as connection information of node 3, port 1 connection node is node 1 and port 2 connection node is node 2, the relay information is set to indicate the relay between the ports 1 and 2.
[0080]
Referring to FIG. 1, the setting contents are as follows: between port P3 of node 1 and port P1 of node 2, between port P4 of node 2 and port 2 of node 3, and port P1 of node 3 and node This indicates that a monitoring control path is set with each port P4. Therefore, as shown in the lower part of FIG. 18, it can be seen that a circulation path of node 1 → node 2 → node 3 → node 1 is formed.
[0081]
In this way, it is possible to check whether or not data circulation occurs based on the node-corresponding connection information and relay information. That is, the monitoring control path check unit 16 in FIG. 2 determines whether data circulation occurs based on the connection information held in the connection information holding unit 18 and the relay information held in the monitoring control path information holding unit 17. You can check whether or not. In FIG. 18, the setting of relay information of port 1 ← → port 4 of node 2 in FIG. 18 is changed to no relay, and the setting of port 1 ← → port 2 of relay information of node 3 is changed to no relay. As a result, there is no monitoring control path between the port P4 of the node 2 and the port 2 of the node 3, so that data circulation does not occur.
[0082]
The present invention is not limited only to the above-described embodiments, and the functions of each part of the monitoring control device (NSP) 10 and the functions of each part of the communication device (node) are realized by the functions of the processor. be able to. Furthermore, the present invention can be applied to a network in which a large number of nodes are connected in a mesh shape.
[0083]
【The invention's effect】
As described above, the present invention is based on the supervisory control device (NSP) 10. Connected in mesh Set relay information for forming a monitoring control path for each node (communication device), and confirm in the monitoring control device that the monitoring control path does not form a loop state by this relay information. It is possible to check whether the relay information set for the node (communication device) has been set normally. Therefore, when adding or removing a node (communication device), changing or adding a monitoring control path, etc. However, there is an advantage that the supervisory control device can easily cope with the integrated management. In addition, since the mask setting of the monitoring control data relay unit of each node (communication device) is performed based on the relay information from the monitoring control device, workability is good and erroneous setting occurs. thing There are no advantages.
[0084]
Also, relay information for each node (communication device) is sequentially set from the monitoring and control device based on the logical distance, so that relay information with a relatively small amount of information is sequentially sent to a large-scale network. A monitoring control path can be sequentially set for each node (communication device). It is also possible to send relay information to all nodes (communication devices) in a lump. In this case, relay routes in the nodes (communication devices) are sequentially set and relayed sequentially. In Therefore, the monitoring and control device can be processed easily. When And the setting of relay information can be completed in a shorter time than when relay information is sent from the sequential monitoring control device to a node (communication device). Have an advantage .
[Brief description of the drawings]
FIG. 1 is an explanatory diagram of a monitoring control system according to an embodiment of this invention.
FIG. 2 is an explanatory diagram of the monitoring control device according to the embodiment of this invention.
FIG. 3 is an explanatory diagram of a node according to the embodiment of this invention.
FIG. 4 is an explanatory diagram of a monitoring control data relay unit according to the embodiment of this invention.
FIG. 5 is an explanatory diagram of monitoring control path information.
FIG. 6 is an explanatory diagram of connection information.
FIG. 7 is an explanatory diagram of initial setting of a node.
FIG. 8 is an explanatory diagram of a monitoring control path setting procedure.
FIG. 9 is an explanatory diagram of a setting sequence according to a logical distance.
FIG. 10 is an explanatory diagram of a setting sequence by batch transmission.
FIG. 11 is an explanatory diagram of monitoring control path setting.
FIG. 12 is an explanatory diagram of a monitoring control path setting sequence.
FIG. 13 is an explanatory diagram of node addition.
FIG. 14 is an explanatory diagram of a setting sequence when nodes are added.
FIG. 15 is an explanatory diagram of monitoring control path change;
FIG. 16 is an explanatory diagram of a sequence of setting change by broadcast communication.
FIG. 17 is an explanatory diagram of a sequence of setting change by a sequential setting instruction.
FIG. 18 is an explanatory diagram of checking data circulation.
FIG. 19 is an explanatory diagram of a network.
FIG. 20 is an explanatory diagram of a conventional monitoring control apparatus.
FIG. 21 is an explanatory diagram of a conventional node.
FIG. 22 is an explanatory diagram of a conventional monitoring control data relay unit.
[Explanation of symbols]
1-6 nodes
10 Monitoring and control device (NSP)
25 Monitoring control data relay unit
P1 to P5 ports
C Monitoring control processing part

Claims (7)

In a monitoring control path setting method executed by a monitoring control system including a plurality of communication devices connected in a mesh form via a transmission line and a monitoring control device that monitors the communication devices ,
Based on the connection information for each communication device in which the monitoring and control device associates the identifiers of a plurality of ports with the identifiers of other communication devices connected to the ports, each of the communication devices for each communication device A procedure for creating relay information indicating whether or not monitoring control data is relayed between ports;
A procedure in which the monitoring control device sends the relay information to the communication device;
It said communication device at the monitoring control data relaying unit that sets the relay route monitoring control data between ports by the mask set, to mask all the relay path between the ports, and receives the relay information from the monitoring control device A procedure for setting a monitoring control path by performing mask setting according to the relay information of the local communication device received from the monitoring control device and held in the relay information holding unit after executing the initial setting procedure to enable
A monitoring control path setting method characterized by causing the monitoring control system to execute . The monitoring control device collectively transmits relay information corresponding to all communication devices, the communication device extracts relay information corresponding to the own communication device, sets a monitoring control path, and sets the set monitoring control path. The monitoring control path setting method according to claim 1, further comprising a step of performing relay transmission of relay information from the monitoring control device according to the above. Procedure wherein the monitoring control unit sends the relay information to the communication device, by referring to the connection information, when the monitoring control paths thus formed on the relay information is not formed orbiting between a plurality of the communication device monitoring control path setting method according to claim 1 or 2, characterized in that it is executed if it is determined. The supervisory control device compares the relay information of each communication device collected by the supervisory control processing unit of the supervisory control device with the relay information held in the supervisory control device, and determines whether the comparison result is inconsistent. 4. The monitoring control path setting method according to claim 1, further comprising a procedure for resetting the relay information . In a supervisory control system having a supervisory control device that monitors a plurality of communication devices connected in a mesh form via a transmission line,
The monitoring control device, as connection information indicating the mutual connection state of the communication devices, for each communication device, another communication device connected to the port in association with identifiers of a plurality of ports of the communication device A connection information holding unit that holds the identifier of
As the relay information for forming the monitoring control path, the monitoring control for creating the relay information indicating the presence / absence of the relay of the monitoring control data between the ports of the communication device for each of the communication devices based on the connection information A path information creation unit;
And a monitor control processing unit for collecting relay information from the control and the communication device sends to the communication device of the relay information created by the monitoring control path information creation unit,
The communication device includes a relay information holding unit that holds the relay information of the communication device received from the monitoring control device ;
A monitoring control data relay unit that sets a relay route between each port that has been subjected to mask setting according to the relay information held in the relay information holding unit ;
After all the relay paths between the ports of the monitoring control data relay unit are masked by the initial setting and the relay information from the monitoring control apparatus can be received, according to the setting instruction from the monitoring control apparatus, A monitoring control processing unit that causes the monitoring control data relay unit to perform mask setting based on the relay information . In a supervisory control device in a supervisory control system for monitoring a plurality of communication devices connected in a mesh form via a transmission line ,
A connection that holds , as connection information indicating the mutual connection state of the communication devices, identifiers of other communication devices connected to the ports in association with identifiers of a plurality of ports of the communication devices for each of the communication devices. An information holding unit;
As the relay information for forming the monitoring control path, the monitoring control for creating the relay information indicating the presence / absence of the relay of the monitoring control data between the ports of the communication device for each of the communication devices based on the connection information A path information creation unit;
A monitoring control device comprising: a monitoring control processing unit that controls transmission of the relay information created by the monitoring control path information creation unit to the communication device and collects relay information from the communication device. In a communication device in a monitoring control system for monitoring a plurality of communication devices connected in a mesh form via a transmission line ,
A relay information holding unit for holding relay information indicating whether or not the monitoring control data is relayed between the ports of the communication device received from the monitoring control device;
And monitoring control data relay unit for setting a monitoring control path to form a relay path between the ports by the mask set in accordance with the relay information,
After the monitoring control data relay unit masks all the relay paths between the ports by the initial setting and can receive the relay information from the monitoring control device, the communication control unit relays the communication control device according to the setting instruction from the monitoring control device. A monitoring control processing unit that causes the monitoring control data relay unit to perform mask setting based on relay information .

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