Multi agent system of the Telecommunication Management Network

专利摘要:
The present invention reduces the amount of management data of each agent by distributing the functions previously executed by one TMN agent to multiple agents, thereby significantly increasing the data generation and processing speed of the TMN agent. Relates to a multi-agent system. In the present invention, when the BIM 20 reads the preparation information for the BSC from the PLD and executes the agent for the prepared BSC, the alarm, fault, and status messages generated from the BSM 30 in the MBL 40 and the SMBL 50 are displayed. And the statistics message is converted into a format suitable for the characteristics of the MO and sent to the appropriate agent, and the agent processes the input message and sends it to the operator (7) to obtain the speed of generating a fast MO instance that is twice as much as the prepared BSC. In addition, since the amount of messages sent from the BSM increases, the performance is much improved, and even if the agent goes down when processing a message, only the corresponding agent is down so that the system can be stably operated.
公开号:KR20000060969A
申请号:KR1019990009670
申请日:1999-03-22
公开日:2000-10-16
发明作者:김창윤
申请人:김영환；현대전자산업 주식회사；
IPC主号:

专利说明:

Multi agent system of integrated management network {Multi agent system of the Telecommunication Management Network}
The present invention relates to a Telecommunication Management Network (TMN), and in particular, by reducing the amount of management data of each agent by distributing the functions used by one TMN agent to a plurality of agents to be executed in multiple. The present invention relates to a multi-agent system of an integrated management network that can significantly increase the data generation and processing speed of a TMN agent.
The conventional TMN agent system ran the agent as one processor, as shown in FIG.
That is, in the related art, the BIM 20 executes the MBL 40, the SMBL 50, and the agent 60, and the MBL 40 and the SMBL 50 are configured from the base station management (BSM) 30. Alarm, fault, status and statistics messages were entered respectively.
In addition, the MBL 40 and SMBL 50 from the agent 60 to the agent 60, the message that changed the alarm, failure, and status messages to match the agent's MO (Managed Object) format is input and at the same time statistical messages to the agent's MO format When a message that has been changed properly is input, the message is transferred from the agent 60 to the operator 70.
At this time, one agent 60 generates thousands or tens of thousands of MOs as shown in the initial execution.
At this time, processing a lot of statistical data sent periodically every 10 minutes takes a lot of time and the performance of the system is also reduced.
For example, the current time to create 20,000 MO instances on SUN Ultra2 is about 34 minutes on average.
This decreases the performance of the system because all data messages from the MBL, the alert, failure, and status instance blocks of the agent, and the SMBL, the statistical interface block, are processed by the agent processor from BSC 0 to 11.
In addition, if a problem occurs while processing the message data, there is a problem that the agent is not available at all because there is only one processor.
The present invention has been made to solve such a conventional problem, and an object of the present invention is to process a large number of MO instance creation time and a large number of data messages sent by the BSM generated during the initial execution of the agent, in one agent Provides multi-agent system of integrated management network that can reduce the time required to create MO instance and improve processing performance of data messages by separating loads given by processing data into agents that generate MOs for each BSC. Its purpose is to.
1 is a view showing a structure that is conventionally operated as one agent
2 is a diagram illustrating a structure operated by multiple agents of the present invention.
<Explanation of symbols for main parts of drawing>
1-12: Multi Agent 20: BIM
30: BSM 40: MBL
50: SMBL 70: Operator
In order to achieve the above object, the present invention reads preparation information about BSC in PLD (Programmable Loading Data), executes agent for BSC that is ready, and executes MBL and SMBL, alarms generated in BSM, BSM, Alarm, fault and status messages are inputted from SMBL and MBL, which converts statistical data messages generated from MBL and BSM, which send fault and status messages to agents, into a format suitable for configuration of MO characteristics. It generates a MO instance for each BSC and includes multiple agents for processing alarm, failure, status, and statistics data messages corresponding to each BSC.
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 2 is a block diagram of the present invention, in which a BIM 20 executing MBL and SMBL for access to multiple agents, a BSM 30 generating a statistical data message every 10 minutes, and the BIM 20 are generated by the BIM 20. FIG. It is executed by the MBL 40 and the BIM 20 to send the alarm, failure, status messages generated in the BSM 30 to the agent, and the statistical data messages generated in the BSM 30 to the characteristics of the MO It is executed by the SMBL (50) and the BIM (20) to convert the format to the format suitable for the configuration of the (Attribute), while receiving the alarm, fault, status messages from the MBL (40) and SMBL (50) The multi-agent (1-12) for receiving the statistical message to generate a MO instance for each BSC by separating into a plurality of agents and processing the alarm, failure, status, statistics data messages corresponding to each BSC, and the multi-agent ( It is composed of the operator 70 receives the information by 1-12).
However, the MBL 40 and the SMBL 50 are connected to each agent 1-12 through a socket, and are configured to transfer a message through the socket.
Referring to the operation of the present invention configured as described above is as follows.
First, the BIM 20 executes the MBL 40 and the SMBL 50 to access the multiple agents 1-12.
Next, the BIM 20 reads the Equip information on the BSC into the PLD and executes the agents divided by the BSCs for the prepared BSCs.
The agent divided by BSC is executed and the MBL 40 and the SMBL 50 connect with the sockets corresponding to the BSC.
Subsequently, when all sockets of the interface block are connected to each prepared BSC, MO interfaces are generated for each BSC.
In addition, alarm, failure, and status messages sent from the BSM 30 to the agent after the completion of the MO instance for each agent (1-12) are converted into a message corresponding to the MO format of the agent through the MBL (40). It is sent to separate agents.
The statistical message sent from the BSM 30 to the agent is converted to the agent's MO format through the SMBL 50 and sent to the agent divided by the corresponding BSC, processed, and then sent to the operator 70.
As described above, the present invention has an effect of rapidly processing data by distributing a plurality of agents to perform a function previously performed by one agent.
In other words, assuming that each BSC has the same shape as the generation time of the existing MO instance, it is possible to obtain a faster generation rate of the MO instance, which is twice as much as the prepared BSC.
In addition, the more the shape is prepared, the greater the amount of messages sent from the BSM, so the performance is much improved than when operating as a single agent.
In addition, even when the agent is down while processing a message, the entire agent is down, but according to the present invention, only the corresponding agent is down, so that the system can be stably operated.

权利要求:
Claims (1)
[1" claim-type="Currently amended] BIM that reads the preparation information for BSC in PLD and runs MBL and SMBL while running agent for prepared BSC.
A BSM for generating statistical data messages every predetermined time;
MBL which is executed by the BIM and sends an alarm, fault, status message generated in the BSM to the agent,
SMBL which is executed by the BIM and converts the statistical data message generated in the BSM to a format suitable for the configuration of the characteristics of the MO to send to the agent,
Receives alarm, fault, status message from MBL, receives statistics message from SMBL, generates MO instance for each BSC, processes alarm, fault, status, and statistics data message corresponding to each BSC and sends them to the operator Multi-agent system of the integrated management network, characterized in that configured including the agent.

类似技术:

---

公开号 | 公开日 | 专利标题

---

EP1613000B1|2008-06-18|Method of dynamic lossless adjusting the bandwidth of the in-line resilient packet ring network

---

EP0591345B1|1996-05-01|Method and system for monitoring a computer system

---

KR101034421B1|2011-05-12|System and method for improved synchronization between a server and a client

---

US5390335A|1995-02-14|Method for modifying system configuration data sets in a telecommunications switching system

---

US6286040B1|2001-09-04|User-friendly interface for setting expressions on an SNMP agent

---

EP2745494B1|2018-01-10|A method and apparatus for determining an event instance

---

JPWO2015146355A1|2017-04-13|Update management system and update management method

---

CN101447884B|2011-08-03|Method for achieving software upgrade by cooperation among network elements, equipment and system therefor

---

US6505256B1|2003-01-07|Automatic synchronization of state colors across a web-based system

---

AU2005307171B2|2009-07-09|Network management apparatus and method based on simple network management protocol

---

US5608720A|1997-03-04|Control system and operations system interface for a network element in an access system

---

US7249359B1|2007-07-24|Method and system for setting expressions in network management notifications

---

US7774404B2|2010-08-10|Managing software component versions within a service oriented architecture

---

US6356917B1|2002-03-12|Monitoring and raising alerts for database jobs

---

RU2608464C2|2017-01-18|Device, method and network server for detecting data structures in data stream

---

US20080189352A1|2008-08-07|Complex event processing system having multiple redundant event processing engines

---

US5848244A|1998-12-08|System and method for time-based real-time reconfiguration of a network

---

JP3483364B2|2004-01-06|SNMP / OSI management gateway device

---

US6324576B1|2001-11-27|Management interworking unit and a method for producing such a unit

---

US6332198B1|2001-12-18|Network device for supporting multiple redundancy schemes

---

CN1175642C|2004-11-10|Clock management method and transmission equipment for synchronous network system

---

CN104657212A|2015-05-27|Task scheduling method and system

---

US6499059B1|2002-12-24|Method of controlling a network element using a service profile and apparatus of the same

---

US20150319032A1|2015-11-05|Method and system for detecting changes in a network using simple network management protocol polling

---

WO2002054252A3|2003-10-02|Method and communication system for exchanging data between users of a bus system

同族专利:

---

公开号 | 公开日

---

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

法律状态:
1999-03-22|Application filed by 김영환, 현대전자산업 주식회사

---

1999-03-22|Priority to KR1019990009670A

---

2000-10-16|Publication of KR20000060969A

优先权:

---

申请号 | 申请日 | 专利标题

---

KR1019990009670A|KR20000060969A|1999-03-22|1999-03-22|Multi agent system of the Telecommunication Management Network|