KR100425500B1 - simulator of the EMS and controlling method therefore - Google Patents

Abstract

The present invention provides a configuration file creation step of creating a configuration file, a configuration file analysis step in which a simulator periodically reads and analyzes a configuration file after the configuration file creation step, and the configuration file. After the file analysis step, the network management system simulator and its control consists of an event simulation step of constructing a structure for event simulation according to the items in the configuration file and transmitting the event to the network management system according to the configured structure to execute the simulation. Provide a method.

As described above, the present invention simulates a network management system unit through a configuration file including event generation sources of various network devices, and executes a sufficient test with various items before interworking the network management system unit with an actual network device. By eliminating potential defects that may exist in the management system part, the operation quality of the network management system part is thus significantly improved.

Description

Simulator and control method of network management system

The present invention relates to a simulator of a network management system and a control method thereof, and more particularly, to a simulator and a control method of the network management system for simulating the network management system through a configuration file containing the event generation sources of various network devices will be.

In general, as the information society develops, as the role of communication network plays an increasing role in society as a whole, the centralization and automation of communication network operation management has emerged as an essential component of communication network. Therefore, in consideration of the importance of network operation management, ITU-T also sets an operating system element such as a network management system as an essential element constituting a communication network as an automation / centralization concept for a communication network.

The network management system as described above is an operation system that usually operates a communication network in the form of automation / centralization. Due to its characteristics, the network management system is connected by various types of data communication networks, for example, SDH optical transmission devices, SONET, or a plurality of SDH devices. To collect and store various types of information from the SDH, and basically provide a function of processing and processing various communication network management information from these information. Therefore, the network management system as described above has a function of executing, for example, event information and the like output from a network device (hereinafter, referred to as NE) transmitted from an online communication module, such as an SDH, in a database table. Is usually performed. However, the network management system as described above typically uses a simulator to test whether the network management system operates normally before actually connecting with the NE.

Then, referring to Figure 1 of the simulator of the conventional network management system as described above, EMS server 71 is embedded with a network management system 70 for processing a variety of events input from a plurality of NE (not shown), And a simulator 72 generating an event to the network management system 70 of the EMS server 71 to form the same event condition as the NE.

In this case, the simulator 72 may be executed by inputting a specific file, for example, "Agent_sim (IP address) (period)", which requires event generation directly from a command line.

Meanwhile, referring to the operation of the simulator of the conventional network management system as described above, first, the EMS server 71 of the network management system unit is connected to the simulator 72 representing the virtual NE, and the file having the same condition as the event of the NE is obtained. Do it yourself by writing.

That is, a user writes directly on the command line of the system where the agent simulator 72 is located, for example, "Agent_sim (IP address) (cycle) Event_Type" to execute the simulator 72.

Here, the IP address is an IP address of the network management system that will receive the corresponding event, and the period refers to an event occurrence period, and the Event_Type indicates which event to generate.

In this case, the simulator 72 analyzes a specific file and generates a corresponding simulation event. For example, when the event requested from the EMS server is a fault alarm having a 30 second cycle, the simulator 72 fails at a 30 second cycle. An alarm is generated and sent to the corresponding EMS server 71. Then, the corresponding EMS server 71 takes appropriate measures by simulation event information input from the simulator 72, for example, a fault alarm, and displays the result. Therefore, the user confirms the function of the current EMS server by using the result displayed on the EMS server 71 and refers to the result of the connection signal with the actual NE.

However, since the simulator of the conventional network management system as described above does not describe the detailed items because the user must manually fill out the necessary items by using a simple file structure on the command line, it is difficult to operate the simulator accordingly. there was.

In addition, since the simulator of the conventional network management system as described above is operated with a simple file structure, it is impossible to simulate the actual situations that may occur in the NE because detailed items cannot be entered, thus significantly reducing the accuracy of the simulation. There was this.

Accordingly, the present invention has been invented to solve the above-mentioned conventional problems, and simulates the network management system through a configuration file including the event generation sources of various network devices. The purpose of the present invention is to provide a simulator and a control method of the network management system that eliminates potential defects that may exist in the network management system by executing sufficient tests with various items before interworking.

Another object of the present invention is to execute a variety of event conditions that can occur in the network device through a configuration file of a relatively simple structure, and accordingly the simulator of the network management system that significantly reduces the manufacturing cost of the simulator of the network management system accordingly To provide a control method.

The present invention for achieving the above object is a configuration file creation unit for creating a configuration file for simulating a variety of events input from a plurality of virtual NE, and the configuration file created by the configuration file creation unit Provides simulator of network management system including simulator that analyzes configuration file periodically and generates various event set according to configuration file and forms the same event condition as actual NE.

Other features of the present invention include a configuration file creation step of creating a configuration file, a configuration file analysis step of periodically reading and analyzing a configuration file by the simulator after the configuration file creation step; After the configuration file analysis step, the network management system simulator consists of an event simulation step of constructing a structure for event simulation according to the items in the configuration file and transmitting the event to the network management system according to the configured structure to execute the simulation. Provides a control method.

1 is an explanatory diagram illustrating a simulator of a conventional network management system.

2 is an explanatory diagram illustrating a simulator of the present invention.

3 is a flowchart of the present invention.

4 is an explanatory diagram illustrating a structure of a configuration file of the present invention.

5 is an explanatory diagram illustrating a structure of a simulator according to a configuration file of the present invention.

<Detailed Description of Codes>

1: Configuration file creation unit

2: EMS server

3: simulator

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The simulator system of the present invention receives and processes various events inputted from a plurality of virtual NEs as shown in FIG. 2, and includes an EMS server 2 including a configuration file creation unit, and the EMS server 2 And a simulator (3) which periodically analyzes the configuration file of the &quot;) and generates various event messages set according to the configuration file to form the same event conditions as the actual NE.

Here, the simulator 3 is composed of a TL1 generator. And, the simulator 3 has the following five conditions, namely

"1. Must support a variety of events.

2. The network management system part should be able to send any specific event needed and be able to send both occurrence and release events.

3. It should be able to generate a lot of events at once.

4. In order to simulate the natural NE's functionality, it must have the ability to randomly generate and release events.

5. The requirements of paragraphs 1 to 4 above shall be applicable by the user in real time. Is designed to satisfy the condition.

In addition, the configuration file is in the form of a text file and is composed of a plurality of items necessary for determining the operation mode of the simulator 3.

Next, a control method applied to the present invention system as described above will be described.

The present invention proceeds to the configuration file creation step (S2) in the initial state (S1), as shown in Figure 3, the network management system creates a configuration file and transmits it to the simulator.

That is, the configuration file creation unit 1 creates a configuration file as a text file as shown in FIG. 4, which configuration file is 1) EMS IP address, 2) Configuration file reading cycle. , 3) TID, 4) Event sending cycle, 5) 15min parameter, 6) 1day parameter, 7) Event type, 8) Event Usage, 9) EventMode, and 10. specific Event No.

1) EMS IP address: a destination address for transmitting an event.

2) Configulation file reading cycle: The cycle that the simulator reads back to modify the configuration file as necessary and reflect the changes.

3) TID: This field indicates the device name and means Target Identification. This information is included in the TL1 Event message. The network management system looks at this TID to recognize from which NE the event was received.

4) Event sending cycle: A cycle to generate an event and send it to the network management system.

5) 15min parameter: Shows the transmission period corresponding to 15 minutes of PM or TCA events. Substantially every 15 minutes these events can be sent. For simulation, we need to receive these events within a short time, so adjust the value of 15 minutes to a shorter time.

6) 1day parameter: Shows the transmission period corresponding to 1day of PM event or TCA event. Substantially these events can be sent every day, so for simulating it is necessary to receive these events within a short time, so adjust the transmission period of one day to a shorter time.

7) Event type: After classifying all possible events, match each index by index and write a string corresponding to the index.

8) Event Usage: Indicates whether or not to send the event (ex: 1 is sent).

9) Event Mode: This item decides the mode when sending an event. The event sending mode is classified into the following three categories.

??) Send only specific events

??) Sending a large amount of events

??) Send one event at a time, but process randomly selected events

For each of the three modes classified, generation and release of an event are repeated according to an event transmission period.

10. specific Event No: When the Event Mode is ??), only a specific event is transmitted. This item determines what the specific event is.

On the other hand, after the configuration file creation step (S2) to proceed to the configuration file analysis step (S3), the simulator periodically reads and analyzes the configuration file.

That is, the simulator 3 reads the configuration file created by the configuration file creating unit 1, and periodically reads and analyzes variable values corresponding to 1 to 10 items of the configuration file. do. At this time, the simulator 3 reads and analyzes the item variable according to the period of the "Configuration file reading cycle" of the configuration file.

After the configuration file analysis step S3, the process proceeds to a specific event occurrence determination step S4 to determine whether an item for requesting the occurrence of a specific event is set in the configuration file. At this time, if the item that requires the occurrence of a specific event is set in the configuration file as a result of the simulator judging during the specific event occurrence determination step (S4), the process proceeds to the specific event generation step (S5) to generate a specific event message. To the network management system.

That is, the simulator 3 periodically reads the configuration file, and when there is an item requiring only a specific event occurrence as a result of analyzing the configuration file, the simulator 3 writes data to the structure to generate the TL1 event message as shown in FIG. 5. do.

For example, the simulator 3 sets a variable of range_check_no (initial value 0) to generate a specific event message and transmits it to the network management system unit 1. If the value is 0, the simulator 3 changes the value to 1 after processing the event. At this time, when sending again after the next cycle has elapsed, since the value of range_check_no is set to 1, the event is canceled and the value of range_check_no is changed to 0 again. After the next cycle of the event has elapsed, since the value of range_check_no is set to 0, the specific event is transmitted to the network management system and the value of range_check_no is changed to 1. Therefore, the simulator 3 repeatedly transmits to the network management system unit 1 the occurrence and release of a specific event at predetermined intervals in the configuration file. Then, the network management system unit 1 executes the simulation function according to the specific event message transmitted from the simulator 3 and displays the result. Therefore, the user confirms the function of the current network management system unit 1 using the result displayed on the EMS server 2 and refers to the result when connecting to the actual NE.

However, if an item for requesting the occurrence of a specific event is set in the configuration file as a result of the simulator's determination during the specific event occurrence determining step (S4), the process proceeds to the mass event generating decision step (S6) and the configuration file. It is determined whether the item is requested to generate a large number of event messages at the same time. In this case, if the item is requested to simultaneously generate a large amount of events in the configuration file as a result of the determination of the mass event generation step (S6), the process proceeds to the massive event generation step (S7) and the set amount Simultaneously generates event messages and sends them to the network management system.

That is, the simulator 3 generates a large number of events by setting a variable called range_check_no (initial value 0) and simultaneously transmits a large number of events to the network management system unit 1. In this case, when the value of range_check_no is 0, the structure of start_no in the structure Is set to 0 and when the value of range_check_no is 1, the value of start_no is set to the maximum number that can occur in the corresponding event type. Here, the generation and release of the simultaneous occurrence of a plurality of events operates in the same way as the generation and release of the specific event.

In addition, the network management system unit 1 executes a simulation function according to the mass event message transmitted from the simulator 3 and displays the result. Therefore, the user confirms the function of the current network management system unit 1 using the result displayed on the EMS server 2 and refers to the result when connecting to the actual NE.

On the other hand, if the item that requires the simultaneous generation of a large number of events is not set in the configuration file as a result of the determination of the mass event generation determination step (S6), the process proceeds to the random event generation and release determination step (S8). It is determined whether an item is requested to be generated at random in the configuration file. Here, if an item is requested to generate an event randomly in the configuration file during the random event generation and release determination step (S8), the process proceeds to the random event generation step (S9). Generates an event message and transmits it randomly to the network management system and releases the transmitted event message.

That is, the simulator 3 randomly selects r_no in the range of 0 to 2 * total number of events. At this time, the simulator 3 sets random_check_no [2 * the total number of events] in the structure to 1 when transmitting the corresponding event to the network management system 1. Here, if the random_check_no [r_no] is 0, the r_no th event message has not been transmitted yet, and if the random_check_no is 1, the r_no th event message has already been transmitted.

Therefore, if the r_no is smaller than the total number of events, the value of random_check_no [r_no + number of events] is set to 0. In this case, this is set to enable transmission if an event corresponding to "r_no + total number of events" is selected next. Means. On the other hand, if r_no is greater than the total number of events, the value of random_check_no [r_no-total number of events] is set to zero.

On the other hand, if the random_check_no [r_no] is 1 in the structure, the simulator 3 recognizes that the r_no-th event message has already been transmitted, and if the random_check_no [r_no] is set to 0, the r_no-th event message is displayed. Recognizes that transmission is interrupted.

Therefore, if the r_no is smaller than the total number of events, the value of random_check_no [r_no + total number of events] is set to 1, which is set to enable transmission if an event corresponding to "r_no + total number of events" is selected next. Means. On the other hand, if r_no is greater than the total number of events, random_check_no [r_no-total number of events] is set to 1 and randomly transmits the event to the network management system 1.

Then, the network management system unit 1 executes the simulation function according to the event message randomly transmitted from the simulator 3 and displays the result. Therefore, the user confirms the function of the current network management system unit 1 using the result displayed on the EMS server 2 and refers to the result when connecting to the actual NE.

Therefore, according to the present invention, since the event processing function that may occur in the network management system unit 1 when interworking with the network device NE is simulated by the simulator 3 in various ways, the network management before the actual NE is connected. The coupling of system parts can be fully tested.

As described above, the present invention simulates the network management system unit through a configuration file including the event generation sources of various network devices, so that sufficient tests are executed with various items before interworking the network management system unit with the actual network device. Therefore, potential defects that may exist in the network management system part are eliminated, and accordingly, the operation quality of the network management system part is significantly improved.

In addition, according to the present invention, since various event conditions that may occur in the network device are executed through a configuration file having a relatively simple structure, the manufacturing cost of the simulator of the network management system unit is also significantly reduced.

Claims (4)

A configuration file creation unit for creating a configuration file that simulates various events input from a plurality of virtual NEs, and a configuration file created by the configuration file creation unit periodically and analyzing the configuration file A simulator of a network management system, comprising a simulator generating various events set according to a file and forming an event condition identical to an actual NE. The configuration file of claim 1, wherein the configuration file includes an item including an EMS IP address, a configuration file reading cycle, a TID, an event sending cycle, a 15min parameter, a 1day parameter, an event type, an event usage, an event mode, and a specific event no. Simulator of the network management system, characterized in that. A configuration file creation step of creating a configuration file, a configuration file analysis step of periodically reading and analyzing a configuration file by the simulator after the configuration file creation step, and a configuration file analysis step Later, the structure of the event management step of configuring the structure for event simulation according to the items in the configuration file, and sending the event to the network management system part based on the structure to execute the simulation, the control of the simulator of the network management system, characterized in that Way. The method of claim 3, wherein the event simulation step comprises generating a specific event and transmitting the specific event to the network management system unit when an item for requesting the occurrence of a specific event is set in the configuration file; If an item is requested to generate a large amount of events in the configuration file at the same time, the multi-event simultaneous generation step of simultaneously generating a plurality of set events and transmitting them to the network management system, and the event message set in the configuration file. And generating a random event and randomly generating the network management system and releasing the transmitted event message.