JPH0828737B2 - Communication system and relay device used in the system - Google Patents

Description

The present invention relates to a communication system in which a central device controls and monitors a plurality of control and monitoring targets via a plurality of relay devices, and a central control device does not set an address for each device to be controlled and monitored. For the purpose of enabling a supervisory control device to uniquely distinguish and control a plurality of devices to be controlled and monitored through a plurality of relay devices, a central device, a plurality of relay devices, In a communication system having a plurality of control and monitoring targets, each of the plurality of relay devices has an input / output port on an upper side and a lower side, and a plurality of input / output ports on the lower side. ,
Reference numerals are assigned so as to be distinguished from each other in each relay device, and each port on the lower side is connected to the upper port of one lower relay device or one of the control and monitoring targets, and the upper side Is connected to one of the lower ports of the upper relay device or the central device, and each of the relay devices is attached to the port in the information received by the lower port. Uplink relay control means for adding the code and transmitting from the upper port, and information received by the upper port removes a code indicating one of the lower port in the own device included in the information, Downlink relay control means for transmitting to the lower side from the port indicated by the reference numeral, the control and monitoring target is connected to any one of the lower side ports of the relay device, and the central device is the target control and monitoring. Connected to the route to the target A code indicating a lower ports of all relay device configured to access said purpose of controlling the monitored by the address obtained by adding in the order of the connection.

[Industrial applications]

The present invention relates to a communication system in which a central device controls and monitors a plurality of control and monitoring targets via a plurality of relay devices.

In recent years, information transmission networks, which have been gradually expanded, have become complicated and organic, and connection of devices in the network, securing of transmission paths thereof, maintenance, etc. have very important elements. Is becoming.

The central supervisory control device that integrally manages the supervisory control function of the network as described above generally collects the supervisory information from each device in the network via a plurality of relay devices, and sends a command for controlling each device. Send.

[Problems to be Solved by Conventional Techniques and Inventions]

In a conventional supervisory control system for an information transmission network, an address is given to each device to be controlled and monitored in the network, and the given address is stored in a central supervisory control device and at the same time, in each device. For example, the given address is set by a hardware switch or the like. As a result, the central supervisory control device can access each control and monitoring target.

However, in the above-mentioned address assignment method, in a large-scale network, it is necessary to set an address to each of a huge number of control and monitoring target devices without error. For example, if a plurality of control and monitoring targets are set, If an address overlap occurs between them, data collision occurs and control and monitoring of these devices becomes impossible.

In addition, if the address setting in the control / monitoring target device is incorrect, the central monitoring / control device may mistakenly recognize the control / monitoring target, and the monitoring information of the wrong device may be given to the central monitoring / control device. However, there is a problem that the control information from the central supervisory control device is given to the wrong device and the control monitoring system is confused.

The present invention has been made in view of the above problems, without setting an address in each device to be controlled and monitored,
It is an object of the present invention to provide a communication system in which a central supervisory control device can perform supervisory control by uniquely distinguishing each device to be controlled and monitored via a plurality of relay devices.

[Means for solving the problem]

FIG. 1 shows the overall configuration of the communication system of the present invention.

In FIG. 1, 1 is a central device, 2 is a relay device, and 3 is a device to be controlled and monitored.

Each of the plurality of relay devices 2 has input / output ports 4 and 5 on the upper side and the lower side, and the input / output port 5 on the lower side.
Is a plurality, and they are respectively numbered so as to be distinguished from each other in each relay device 2, and each of the lower ports 5 is an upper port of one lower relay device, or the control and monitoring target 3 , And the upper port is connected to one of the lower ports of the upper relay device or to the central device 1.

The control / monitoring target 3 is connected to any one of the lower ports of the relay device 2.

The central device 1 is connected to all the control and monitoring targets 3 directly or via one or a plurality of relay devices 2.

FIG. 2 shows the basic configuration of each relay device 2 of FIG.

In FIG. 2, 4 is the upper port, 5 (5 ₁ , 5 ₂ , ...
_5n ) is a plurality of lower ports, 6 is an upstream relay means, and 7 is a downstream relay means.

The upstream relay control means 6 adds the code attached to the port to the information received by the lower port 5 and transmits the information from the upper port 4. The downlink relay control device 7
The information received by the upper port 4 is transmitted to the lower side of the port indicated by the code by removing the code indicating one of the lower ports in the own device included in the information.

[Operation] FIG. 3 is an explanatory diagram of a procedure for adding a port address in the present invention.

As shown in FIG. 3, when each relay device 2 is branched and connected, the relay device which receives the information from the lower side can recognize the physical port, and therefore the port number is used as the port in the frame. Add it to the address field and send the frame from the upper port.

When the relay devices 2 are connected in a cascade manner, the above operation is repeated to finally reach the uppermost central device 1.

For example, if the central unit 1 transfers the initial state from all control and monitoring targets 3 at the time of system startup,
At that time, the above-mentioned port address can be received, and by going back this port address, and by recognizing from which port in the central device 1 itself the information frame has passed, Therefore, it is possible to access each control and monitoring target 3 without error.

〔Example〕

FIG. 4 shows the connection of the supervisory control device C, the plurality of central monitoring devices r1 to r12, ..., And the supervisory control system of the information transmission network including the plurality of network elements NE, as an embodiment of the communication system of the present invention. It is a figure which shows an example.

The upper monitoring device C corresponds to the central device 1, the intermediate monitoring devices r1 to r12 ... Correspond to the relay device 2, and the network element NE is the control and monitoring target 3. The network element NE is, for example, an optical communication device, a multiplexing device or the like that constitutes an information communication network.

FIG. 5 is a schematic configuration diagram of the intermediate monitoring device in the embodiment of the present invention.

In FIG. 5, 10 is a controller, 11 is an upper communication control circuit, 12 to 14 are lower communication control circuits, and 15 respectively.
And 16 are upstream and downstream upper transmission lines, 17 and 18, 19 and 20, and 21 and 22, respectively.
Are a plurality of pairs of lower-side transmission lines, each consisting of a pair of upstream direction and a pair of downstream direction.

The upper and lower communication control circuits 11 and 12 to 14 are provided corresponding to one port, respectively. For example, HDLC ABM (Asynchronous Balance) is provided between the communication control circuits 11 and 12 to the opposite device.
The communication control is performed so that the communication can be performed asynchronously from either direction by a procedure such as d Mode).

The controller 10 has an MPU and a data buffer (not shown), adds the port number of the port to the port address field of the information frame received from each port on the lower side, and the upper side communication control circuit 11 sets the upper port 4 Control is performed so that the data is transmitted to the device facing the higher side. Also, the information frame received at the upper port 4 has the port number indicating one of the lower ports in its own device included in the port address field of the information removed, and is placed at the lower side of the port indicated by the port number. Control to send to the opposite side.

FIG. 6 shows a network element NE of the communication system based on the connection shown in FIG.
6 shows an example of the configuration of a port address field of an information frame transmitted / received at each port of the higher-level monitoring device C when communication is performed with the port.

For example, the monitoring device C may include the intermediate monitoring devices r1, r3, and
In the port address field of the information frame transmitted from the network element NE connected via r6 to the upper monitoring apparatus C, the number 3 of the port connecting the network element NE in the intermediate monitoring apparatus r6.
Is added to the upper intermediate monitoring device r3, and the intermediate monitoring device r3 is added with the number 2 of the port connecting the above intermediate monitoring device r6 to the upper relay device r1. In the monitoring device r1, the above intermediate monitoring device r3
Is added to the port number 1 for connecting to the upper monitoring apparatus C.

The upper monitoring apparatus C recognizes the above-mentioned port address field and the port received by itself as the address of the above-mentioned network element NE.

The upper-level monitoring device C issues a simultaneous reset command (global reset command) to all lower-level devices when necessary, such as when the system starts up or when settings are changed.

In response to this, each network element in the system transfers the initial state in its own device to the host monitoring device.
Based on the port address field of the information frame at the time of this transfer and the port received by the own device, the higher-level monitoring device C recognizes what kind of route each information frame has taken, as described above. The port address field and the port number received by the own device are stored. In this way, the upper monitoring apparatus can access each network element without any mistake.

〔The invention's effect〕

According to the present invention, the central monitoring control device can control each of a plurality of control and monitoring target devices via a plurality of relay devices based on an actual connection state without setting an address in each control and monitoring target device. It is possible to uniquely distinguish and perform the monitoring control.

[Brief description of drawings]

1 is an overall configuration diagram of a communication system of the present invention, FIG. 2 is a basic configuration diagram of the relay device 2 of FIG. 1, FIG. 3 is an explanatory diagram of port address addition in the present invention, and FIG. 5 is a diagram showing an example of connection in the embodiment of the present invention, FIG. 5 is a schematic configuration diagram of an intermediate monitoring device in the embodiment of the present invention, and FIG. It is a figure which shows the port address which the information frame at the time of communicating with each network element NE has in the port of the high-order monitoring apparatus C. [Explanation of reference numerals] 1 ... Central device, 2 ... Relay device, 3 ... Device for control and monitoring, 4 ... Upper port, 5 (5 ₁ , 5 ₂ , ... 5 _n ) ...
… Several lower ports, 6 …… Upstream relay means, 7 …… Downward relay means, 10 …… Controller, 11 …… Upper side communication control circuit, 12 to 14 …… Lower side communication control circuit, 15,16 ... … Higher side transmission line, 17,18,19,20,21,22 …… Lower side transmission line.

Claims (2)

[Claims] 1. A central device (1) and a plurality of relay devices (2)
And a plurality of control and monitoring targets (3), each of the plurality of relay devices (2) has an input / output port (4,5) on an upper side and a lower side, There are a plurality of input / output ports (5) on the lower side, and each relay device (2)
Are assigned so as to be distinguished from each other, and each of the lower ports (5) is connected to the upper port of one lower relay device or one of the control and monitoring targets (3), The upper port is connected to one of the lower ports of the upper relay device or the central device (1), and each relay device (2) is connected to the lower port (5). The received information, the upstream relay control means (6) for adding the code attached to the port and transmitting from the upper port (4), and the control and monitoring target (3) is the relay device. The central device (1) is connected to any one of the lower side ports of (2), and is connected to all control and monitoring targets (3) directly or through one or more relay devices (2). The central device (1) is controlled by each control and monitoring target (3).
To the lower side ports of all the relay devices (2) connected to the route to the central device (1) based on the code added to the central device (1). Communication system. 2. An input / output port (4,
5), and the plurality of lower-side input / output ports (5) are provided with reference numerals so as to be distinguished from each other in the self-device (2), and further, the lower-side ports (5) ) In the information received in
A relay device comprising an upstream relay control means (6) for adding the code attached to the port and transmitting from the upper port (4).