KR100767553B1 - Method for communication state management of remote network element in synchronous digital hierarchy system - Google Patents

Abstract

The present invention provides a method for managing a communication state of a remote device in an optical transmission system, comprising: a first step of setting a remote device connected to a gateway device and an optical cable as an object for checking an alive; And a second step of automatically reporting and communicating the communication status of the remote device to the client after the first step, so that the status of the remote device can be grasped in real time by the client of the GUI and physically separated from the server if there is an error. In this state, it is possible to guarantee stable communication with the remote device independently of the server.

Description

Method for communication state management of remote network element in synchronous digital hierarchy system

1 is a block diagram of a general synchronous digital hierarchy system;

2 is a flowchart illustrating a communication state management method of a remote device in a conventional optical transmission system;

3 is a flowchart illustrating a communication state management method of a remote device in an optical transmission system according to the present invention.

Explanation of symbols on the main parts of the drawings

10: client 20: Ethernet

30: server 31: CSM

32: SCM 40: Database

50: gateway device 60: NE network

70: remote device

The present invention relates to a stable communication state management of a graphical user interface (GUI) in a synchronous digital hierarchy (SDH) system with an SDH. A method for managing the communication status of a remote device in an optical transmission system that grasps the status in real time from the GUI client and ensures stable communication with the remote device independently of the server even when there is an error. will be.

In general, SDH is a standard technology for synchronous data transmission on optical media, and is internationally equivalent to SONET (Synchronous Optical Network). Both technologies are faster and less expensive to access networks than traditional PDH (Plesiochronous Digital Hierarchy) devices. SDH uses the STM series and speeds that follow. These include STM-1 at 155 Mbps, STM-4 at 622 Mbps, STM-16 at 2.5 Gbps, and STM-64 at 10 Gbps.

Therefore, in operating the SDH system, the prior art was able to know the communication connection state of the remote device only after the client attempts to communicate by requesting a command to the remote device to determine the communication status.

1 is a block diagram of a general synchronous digital hierarchy system.

Here, reference numeral 10 is a client which is a terminal to be used by the operator, and 20 is a connection network between the client 10 and the server 30 and a connection network between the server 30 and a gateway network element (GNE) 50. , 30 is a server in response to a request of the client 10 transmitted through the Ethernet 20, 31 is a CSM (Client Server Manager, located in the server 30 to manage the client 10, 32 is an SCM (SDH Connect Manager) which is located in the server 30 and manages Network Element (NE).

In addition, reference numeral 40 is a database (Database, DB) connected to the server 30, 50 is a gateway device (GNE) is connected to the server 30 via the Ethernet 20 to serve as a gateway, 60 Is an NE network which is an optical cable connecting the gateway device 50 and the remote device (RNE) 70, and 70 is a remote device connected to the gateway device 50 via the NE network 60.

Therefore, in the operation of the SDH system, the prior art is largely composed of a graphical operator interface (GUI), which is a manager, and an NE, which is an agent. It is connected to the gateway device 50, the remote device 70 is connected to the gateway device 50 and the optical cable. In addition, the GUI, which is a manager of the SDH, performs basic operations by the client 10, which is a terminal that the operator will use, and the server 30 responding to the request of the client 10, and again, the server 30 receives the client 10. It is operated by the CSM 31 in charge of the management of < RTI ID = 0.0 >) < / RTI >

Therefore, the server 30 collects and manages information of the plurality of NEs, and manages local network login and logout of the web client 10. The client 10 connected to the Ethernet 20 may monitor the local network by performing NE control and monitoring by logging in to the NE.

2 is a flowchart illustrating a communication state management method of a remote device in a conventional optical transmission system.

As shown in the drawing, when the client 10 receives a request for status determination of the remote device (RNE) 70, the command of the client 10 is transmitted through the command queue of the server 30 (GNE) ( Transmitting to step 50) (ST11) (ST12); The gateway device (50) is passed to the processor of the remote device (RNE) (70) via an optical cable, and then determining whether there is a response from the remote device (ST14); If there is no response from the remote device (70), determining whether a timeout has occurred (ST15); Determining whether the remote device 70 responds and whether or not the timeout has occurred may be performed to determine a communication connection state of the remote device 70 (ST16).

When described in detail with reference to the accompanying drawings of the operation of the prior art configured as follows.

First, the operation of the server 30 is divided into CSM 31, SCM 32, DBM (Database Manager, not shown in the figure).

Thus, the CSM 31 performs a manager function for managing communication between the client 10 and the server 30. The operator registered in the DBM logs in to the client 10 through its ID, and the client 10 registers the equipment to be managed by the logged-in operator.

SCM 32 requires the registration of the equipment managed by the server (30). When the device is registered, the server 30 performs an ACT-USER (login) on the device, and then inquires the automatic report generated during the time when the communication between the server 30 and the corresponding device is lost, and then connects the database with the server 30. Each item is stored at 40. This process is performed for various history management. At this time, the corresponding equipment becomes the gateway device 50.

DBM requires an operator ID required to log in from the client 10. Operator IDs have a class, and the class limits the system commands that can be controlled by the operator.

On the other hand, the equipment can register the gateway device 50 connected to the server 30 and the Ethernet 20, and also to the remote device 70 connected to the gateway device 50 and the optical cable NE network 60 without the IP You can register.

When the client 10 selects one of the devices registered by the operator, communication is performed with the corresponding device.

Responses to requests in communication include <success>, <failure>, and <no response>.

In order to check the physical communication disconnection in the communication between the client 10 and the server 30, the CSM 31 of the server 30 periodically checks the communication state by performing a ping-pong process.

In addition, the SCM 32 also performs a ping-pong process to check the physical communication between the server and the equipment.

The response of <success> or <failure> among the responses to the request during communication can be confirmed by the operator 10 by the operator, but the processing is delayed or deadlocked due to an unexpected situation of the command requested by the client 10. When this occurs, the operator can not wait for a response to the request, so the timeout value is applied to the CSM 31 and the SCM 32.

This is when the plurality of clients 10 are managed by the CSM 31 of the server 30 when the command requested by the plurality of clients 10 is eventually delivered to the gateway device 50 through the server 30, Since the processor of the gateway 50 processes the requests one by one, the request command of the client 10 is accumulated in the command queue of the server 30 due to the processing speed of the command. This may be necessary because timeouts can occur.

Accordingly, when the SCM 32 communicates with the remote device 70 through the gateway device 50 (hereinafter referred to as “power communication”), the command requested by the client 10 is transferred through the command queue of the server 30. Delivered to device 50.

And it is transmitted to the processor of the remote device 70 through the NE network 60, which is an optical cable connected to the gateway device (50).

In this case, a delay may occur due to the command processing state of the gateway device 50 and the capacity limit of the cable between the gateway device 50 and the remote device 70, and thus, a timeout value needs to be applied.

Then, the operator registers the device to be managed by the logged-in client 10 to operate the corresponding device.

However, this conventional technology has the following problems.                         

That is, when the operator registers the equipment to be managed by the client 10 in which the user logs in and operates the equipment, the ACT-USER is the first communication between the gateway device 50 and the server 30 for the gateway device 50. It is possible to know the communication connection status through the (login) and the ping-pong process and the response or timeout process to the command requested by the client 10 continuously.

Therefore, when the Ethernet 20 connected to the server 30 is disconnected or an abnormality occurs in the processor of the server 30, the operator of the client 10 may change the state of the gateway device 50 through ping-pong processing or timeout in real time. You can see how.

However, the operator has a problem in that the communication connection status is unknown unless the operator requests a command to the remote device 70 to communicate with respect to the state of the remote device 70. That is, the gateway device 50 connected to the server 30 by the Ethernet 20 with a unique IP (Internet Protocol) is continuously ping-pong processing of the gateway device 50 even if the operator does not request a command. You can see the communication connection status.

On the other hand, in the case of the remote device 70 is connected to the gateway device 50 by an optical cable, the operator requests a command to the corresponding gateway device 50, the communication connection state of the remote device 70 only through the response and timeout occurs As can be seen, there is a problem that the operator cannot monitor the communication connection state of the remote device 70 while communicating with the gateway device 50.

Therefore, the present invention is proposed to solve the above-mentioned conventional problems, and an object of the present invention is to physically separate from the server when there is an abnormality in real time in the client of the GUI of the remote device that is the power system. The present invention provides a method for managing a communication state of a remote device in an optical transmission system capable of ensuring stable communication with a remote device independently of a server.

Communication state management method of the remote device in the optical transmission system according to an embodiment of the present invention to achieve the above object,

A first step of setting a remote device connected to the gateway device via an optical cable as the target of the alive check; And a second step of automatically reporting the communication status of the remote device after the first step and reflecting it to the client.

Hereinafter, an embodiment of the present invention configured as described above, according to the technical spirit of the communication state management method of the remote device in the optical transmission system will be described in detail with reference to the drawings.

3 is a flowchart illustrating a communication state management method of a remote device in an optical transmission system according to the present invention.

As shown therein, a first step (ST21 to ST26) of setting the remote device 70 connected to the gateway device 50 by an optical cable as an Alive Check target; It includes a second step (ST27 ~ ST30) to automatically report the communication state of the remote device 70 after the first step to reflect to the client (10).                     

The first steps ST21 to ST26 may include a request step ST21 of requesting registration information of the gateway device 50 from the server 30 to the gateway device 50; If the gateway device 50 has registration information of the gateway device 50, the server 30 designates a remote device 70 as the target for checking alive with the gateway device 50 (ST22). (ST23).

The target specification step (ST22) (ST23) is registered, including the system ID and the automatic report time interval of the remote device 70.

In the first step ST21 to ST26, if there is no registration information of the gateway device 50 in the gateway device 50, the server 30 exchanges the remote device 70 with the gateway device 50. A non-target specification step (ST25) for designating an alive check non-target; A generation discrimination step (ST26) for determining whether to generate a registration of the gateway device (50) in the gateway device (50) after the non-target specification step; If you want to create a registration of the gateway device 50 in the generation discrimination step ST26, perform the target specifying step ST23, and generate a registration of the gateway device 50 in the generation discrimination step ST26. If not, further comprising the step of performing the non-targeting step (ST25).

The first steps ST21 to ST26 may include a change discrimination step (ST24) for determining whether to change the registered information of the gateway device (50) after performing the target specifying step (ST23); Returning to the second step ST27 to ST30 if the registration information is not changed in the change judging step ST24; If the registration information is to be changed in the change discrimination step (ST24), the non-targeting step (ST25) to designate the remote device 70 as the live check non-target with the gateway device 50 in the server 30; ; A generation discrimination step (ST26) for determining whether to generate a registration of the gateway device (50) in the gateway device (50) after the non-target specification step; If you want to create a registration of the gateway device 50 in the generation discrimination step ST26, perform the target specifying step ST23, and generate a registration of the gateway device 50 in the generation discrimination step ST26. If not, further comprising the step of performing the non-targeting step (ST25).

The second step (ST27 ~ ST30), the process operation step (ST27) for operating the alive check process for the remote device 70; A timeout judging step (ST28) for judging whether a timeout has occurred after the alive check process is started; If the timeout occurs, the server 30 notifies the client 10 of the communication disconnection between the gateway device 50 and the remote device 70 and maintains the remote device 70 by an operator. It includes the automatic reporting step (ST29) (ST30) to be made.

In the timeout determination step ST28, the timeout value is set to twice the automatic report time interval of the remote device 70.

The operation of the communication state management method of the remote device in the optical transmission system according to the present invention configured as described above will be described in detail with reference to the accompanying drawings.

First of all, the present invention grasps the state of the remote device 70 in real time from the client 10 of the GUI, and when there is an error, the stable communication with the remote device 70 independently of the server 30 even in a physically separated state from the server. To ensure that.

Thus, the remote device 70 connected to the gateway device 50 and the NE network 60, which is an optical cable, registers its own system ID and automatic report time interval in the gateway device 50, and then, the gateway device 50 registers a certain time in its gateway device 50. Send an automatic report for live checks at intervals.

This can be done with some sort of ping pong. That is, the remote device 70 notifies the gateway device 50 of its own system ID and the automatic report time interval for checking the alive, and transmits an automatic report of a predetermined standard at the corresponding time interval to inform that the communication state is normal.

The server 30 stores information about all NEs managed by the SCM 32 in the database 40.

At this time, the gateway device 50 inputs the system ID and the automatic report time interval value of the remote device 70 connected to the gateway device 50 to the database 40, and transmits the value to the server 30 through the gateway device 50. During the automatic report is to check whether the automatic report for the live check of the remote device 70 connected to the gateway device 50 is transmitted from the corresponding remote device at the automatic reporting time interval.

At this time, the timeout value of the automatic check for alive check is twice the automatic report time interval of the total remote device 70.

Then, the server 30 makes a status value flag of the remote device 70 so that the report can be automatically reported to the client 10 whenever the value changes, and the client 10 automatically reports the time of the remote device 70. It provides the operator with the communication connection state of the remote device 70 within the error time of a multiple of the interval value.

In this way, the present invention is to determine the status of the remote device in real time in the client of the GUI to ensure stable communication with the remote device independent of the server even if physically separated from the server if there is an error.

Although the preferred embodiment of the present invention has been described above, the present invention may use various changes, modifications, and equivalents. It is clear that the present invention can be applied in the same manner by appropriately modifying the above embodiments. Accordingly, the above description does not limit the scope of the invention as defined by the limitations of the following claims.

As described above, in the optical transmission system according to the present invention, the method for managing a communication state of a remote device goes beyond the NE communication state processing of a conventional GUI that manages only the communication state of a gateway device connected to a server and an Ethernet to a gateway device and an optical cable. There is an effect that can automatically manage the communication status of the connected remote device. Accordingly, a plurality of operators can manage their gateway devices and remote devices from a plurality of clients with an operator ID registered in the server.

In addition, the present invention can be configured up to 16 NE in one network. 16 is the peak value that maximizes the processing power of the server and minimizes the load on the system. At this time, more than one IP is required. Up to 16 NEs can be assigned an IP only to the gateway device, and the remaining remote devices are connected to the gateway device via an optical cable. Operators can use the client-server-gateway system connected via Ethernet to access the client anywhere and securely manage the gateway and remote devices through the server. Accordingly, there is an advantage that the communication status of the equipment can be clearly understood even if the corresponding equipment does not directly request a command.

Claims (7)

A first step of setting a remote device connected to the gateway device via an optical cable as the target of the alive check; And a second step of automatically reporting a communication state of the remote device after the first step and reflecting the communication state to a client. The method of claim 1, wherein the first step, A request step of requesting, from a server, a registration information of said gateway device to a gateway device; If the gateway device has the registration information of the gateway device, the server communication state of the remote device in the optical transmission system, characterized in that performing the step of specifying a remote device as the target of the alive check with the gateway device; How to manage. The method of claim 2, wherein the target specifying step, Method of managing the communication status of the remote device in the optical transmission system, characterized in that the registration including the system ID and the automatic reporting time interval of the remote device. The method of claim 2, wherein the first step, A non-target specifying step of designating, by the server, the remote device as an unchecked target for live check with the gateway device if there is no registration information of the gateway device in the gateway device; A generation discrimination step of determining whether to generate a registration of the gateway device in the gateway device after the non-target specifying step; Performing the target specifying step if the registration of the gateway device is to be generated in the generation determining step; and performing the non-target specifying step if the registration of the gateway device is not intended to be generated in the generating discriminating step; Communication status management method of a remote device in the optical transmission system, characterized in that performing. The method of claim 2, wherein the first step, A change discrimination step of determining whether to change registration information of the gateway device after performing the target specifying step; Returning to the second step if the registration information is not changed in the change judging step; A non-target specifying step of designating, by the server, the remote information as the non-target for checking alive with the gateway device if the registration information is to be changed; A generation discrimination step of determining whether to generate a registration of the gateway device in the gateway device after the non-target specifying step; Performing the target specifying step if the registration of the gateway device is to be generated in the generation determining step; and performing the non-target specifying step if the registration of the gateway device is not intended to be generated in the generating discriminating step; Communication status management method of a remote device in the optical transmission system, characterized in that performing. The method of claim 1, wherein the second step, A process running step of running an alive check process for the remote device; A timeout discrimination step of determining whether a timeout occurs after the alive check process is started; And the automatic reporting step of informing the client of the disconnection between the gateway device and the remote device if the timeout occurs and allowing the remote device to be maintained by an operator. Communication status management method of the remote device in the optical transmission system. The method of claim 6, wherein the timeout determination step, And setting a timeout value to twice the automatic report time interval of the remote device.

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