KR101206159B1 - Management system and method for smart grid network having private ip - Google Patents

Abstract

The present invention provides a smart grid communication network management including a management protocol (SNMP) manager for generating a protocol data unit (PDU), a management protocol (SNMP) agent for receiving the protocol data unit, and a device for a smart grid having a private IP address. In the system, the protocol data unit includes the private IP address information, relates to a smart grid communication network management system having a private IP network.

Description

MANAGEMENT SYSTEM AND METHOD FOR SMART GRID NETWORK HAVING PRIVATE IP}

The present invention relates to a method and system for integrated monitoring of fault and performance information for a management device including a device in a WAN section and a device in a HAN section in a smart grid.

Power Line Communication (PLC) is a technology that enables the construction of a network for communication by sending data signals to existing power lines to provide power to homes or offices.

In recent years, many studies have been conducted around the world to use these power lines as a means of communication to establish a backbone network and access network or to use them as supplementary services such as remote meter reading service, home networking service, and high-speed Internet service. It is becoming.

Like other communication networks, the network using the power line communication technology requires management through monitoring and control to efficiently use resources and provide safe operation and service. And when various value-added services are developed and related network equipments also appear, the importance of management to measure the performance and solve errors of network resources will become more important.

In the conventional power line communication, a network is independently provided for each chipset, and services are provided. Each vendor defines a management information base (MIB) to independently manage a network. have.

In addition, in the related art, when various equipments become a multi-vendor power line communication network mixed with each other, overlapping information among independent management information determined by each vendor is integrated and managed.

1 is a diagram illustrating a multi-vendor power line communication network management system according to the prior art.

The conventional multi-vendor power line communication network management system 100 extracts common management information of power line communication equipment into a database 120 as shown in FIG. 1, and manages information of each vendor mapped to common management information (MIB). A manager server that stores and manages OIDs is configured to extract and manage the OIDs of the MIBs, and extract the OIDs mapped to the OIDs of the vendors to generate SNMP messages and transmit them to the powerline communication equipment. We tried to overcome the inefficiency by reducing the management amount of.

However, in the prior art, there is no configuration for connection processing between the public IP network and the private IP network.

Therefore, the present invention relates to a method and system for integrated monitoring of fault and performance information of a management device composed of devices in a WAN section and devices in a HAN section in a smart grid, and focuses on public IP networks and smart grids in the WAN section. The purpose of this paper is to solve the problems of smart grid device management due to different problems between private IP networks in the HAN section. In addition, the management device and the management system generally manage each device using the SNMP protocol. The management information (MIB) to be managed in the smart grid environment has various MIBs for each company and device. We have solved this problem effectively and proposed SNMP message structure for access processing between private IP network and public IP network.

The present invention provides a smart grid communication network management including a management protocol (SNMP) manager for generating a protocol data unit (PDU), a management protocol (SNMP) agent for receiving the protocol data unit, and a device for a smart grid having a private IP address. In the system, the protocol data unit includes the private IP address information, relates to a smart grid communication network management system having a private IP network.

The protocol data unit may have a header part and a body part, and the private IP address information is included in the header part.

The private IP address information is stored in the management protocol manager and the management protocol agent.

Here, the management protocol manager may store overlapping common management information (Common MIB) among management information (MIB) of devices for the smart grid and individual management information (PrivateMIB) according to each smart grid device. And a database storing Object Identifier (OID) values of devices for each smart grid mapped to the common management information and the individual management information.

Particularly, the header part of the protocol data unit may further include an object identifier value mapped to management information of the devices for the smart grid.

The header unit of the protocol data unit may include IP address information and port information of the management protocol manager.

The body of the protocol data unit may include management information of the smart grid device.

The management protocol agent may include a parsing processor configured to separate the header part and the body part of the protocol data unit and store the header part in a queue.

In addition, the management protocol agent is characterized in that the proxy server (Proxy Server).

The present invention provides a protocol data including a header part including an IP address of a management protocol manager, a private IP address of a device for a smart grid, and an object identifier of the device for the smart grid, and a body part including management information of the device for the smart grid. Receiving a unit from the management protocol manager; Separating and storing the header portion of the received protocol data unit in a queue; And transmitting the body portion of the received protocol data unit to a smart grid device having the private IP address.

Also, receiving a response from the device for a smart grid having the private IP address; And generating a protocol data unit including the received response information and the IP address of the management protocol manager stored in the queue, and transmitting the generated protocol data unit to the management protocol manager.

The present invention is capable of monitoring a smart grid management device network in which a public IP network and a private IP network are mixed. In addition, the efficiency of network management is increased through device-specific management and zone-specific network management through proxy object identifier, and development time and cost can be reduced by various types of device common-MIB.

1 is a diagram illustrating a multi-vendor power line communication network management system according to the prior art.
2 is an overall configuration diagram for proxy processing and common-MIB processing in a smart grid device (SG device) integrated management system environment according to the present invention.
3 is a block diagram for mapping the common management information (Common MIB) of the overlap between the individual management information (Private MIB) and the management information of the devices for smart grid according to the equipment of different companies.
4 is a procedure of inputting modeling information to be managed in common management information by taking information from the SG device based on the modeling information of the smart grid device to be integrated and managed.
5 is a MIB information diagram of a proxyObjectTable for ProxyAgent for managing smart grid devices in a private IP network.
6 is an SNMP PDU structure diagram for managing a smart grid device.
7 is a detailed diagrammatic process diagram illustrating a proxy processing unit and an SNMP transmission / reception processing unit in a management protocol agent.
8 is a diagram of an overall process according to the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings.

2 is an overall configuration diagram for proxy processing and common-MIB processing in a smart grid device (SG device) integrated management system environment according to the present invention.

The system according to the present invention comprises a management protocol (SNMP) manager 200, a management protocol agent 240 and a device for smart grid 280.

The management protocol manager 200 includes a data processor 210, an SNMP processor 230, a DB server 220, and a MIB 240 for SG device integrated management.

The data processor 210 generates a protocol data unit (PDU) and transmits the generated message to the management protocol agent 240. The SNMP processor 230 periodically requests data from the SG device 280 according to a predetermined cycle. The DB server 220 and the MIB 240 for SG device integration management store management information of the SG devices 280 and object identifiers (OID) values of the SG devices 280 mapped to the management information. In this regard will be described in detail with reference to FIG.

3 is a block diagram for mapping the common management information (Common MIB) of the overlap between the individual management information (Private MIB) and the management information of the devices for smart grid according to the equipment of different companies.

The common management information is managed by dividing into the configuration MIB 330, the performance MIB 340, and the failure MIB 350. The items of Mapping-MIB 320 are SysObjectID item which is identifier of individual management information 310, OID item of individual management information, OID item of common management information, ItemType (0,1) item according to collection status, collection period. Separated by pollPeriod according to each management. Such items can be stored by mapping each management information in a table format. In addition to storing the common management information separately, mapping and storing the individual management information, it is possible to more efficiently manage the MIB and OID.

Again, in FIG. 2, the management protocol agent 240 includes an SNMP transmit / receive processing unit 250 and a proxy processing unit 260.

The SNMP transmission / reception processing unit 250 is a Recv process coming from the management protocol manager 200 and processes the SNMP transmission to the SG device 280.

As described later, the proxy processing unit 260 divides the data PDU received from the management protocol manager 200 into a header part and a body part, and stores the header part in a queue.

SG device 280 is composed of a device 282 having a private IP network, a device 284 having a public IP network largely depending on the environment. In the SG device, the response by request, whether private network or public network, is normally performed.Trap message processing is processed by Trap Daemon IP (286) of the SG data concentrating unit by configuration and sent to the proxy processing unit in the SG data concentrating unit. In operation 260, the PDU is converted into proxy data and transmitted to the management protocol manager 200.

Here, the management protocol agent 240 may be a proxy server.

4 is a procedure of inputting modeling information to be managed in the common management information by taking information from the SG device 280 based on the modeling information of the smart grid device to be integrated and managed.

On the screen 410 of the management protocol manager 400, input the private IP of the SG device 480 and the external IP of the management protocol agent 440 to request the SysObjectID (system 2) of the standard MIB-2 in the RFC1213. Request 402 to the SG device 480 installed in the field.

Upon receiving the response message, the management protocol manager 400 compares the SysObjectID in the Mapping-MIB 320 of FIG. 3 to determine whether the management device is a management device (404). If it is determined that the management device is stored in the master configuration DB (425). The master DB 425 stores configuration, performance, and fault information according to the modeled SysObjectID, and additionally manages collection cycles and mapping information. If the device is not managed, the device may be notified and terminated.

5 is a MIB information diagram of a proxyObjectTable for ProxyAgent for managing smart grid devices in a private IP network. In FIG. 2, stored in the management protocol manager 200 and the management protocol agent 240, the following items are required for the management of the SG device 280.

ProxyObjectEntry of ProxyObjectTable has ProxyIndex, ProxySysObjectID, ProxyNumber, ProxyPort, ProxyNumberType.

ProxyIndex is used to distinguish the SG device 280 from the management protocol agent 240 in FIG.

ProxySysObjectID is a value for distinguishing the management protocol agent 240 representing the network type address of proxyNumberType. In case of TCP / IP stack network, it means private network IP address which is real IP and in case of HDLC stack, it means HDLC address.

ProxyPort is a SNMP-port of standard SNMP Get and stores port information for SNMP agents, which are different environments, in the management protocol agent 240 of FIG. 2.

proxyNumberType is defined as INTEGER {other (1), ip_address (2), mac_address (3), hdlc_address (4)} as a method for visiting the management protocol agent 240 of FIG. In the case of RS485, Ethernet, Serial, etc., as the connection interface between the 240 and the SG device 280, the protocol form for finding the SG device 280 is shown. As a form, there are proxyNumberType setting settings for an IP address in a private network, an HDLC address indicating an HDLC frame address, an IP address, and the like.

Then, when generating a protocol data unit (PDU), the information can be taken.

6 is an SNMP PDU structure diagram for managing a smart grid device. It consists of a proxyHeader (header section) and proxyBodyPDU (body section). An SNMP transmitter of the data processor 210 of FIG. 2 obtains a private IP and management information to configure a header and a body. The body part is generated by variable-binding the MIB information required according to the PDU type for information to be obtained by the SG device 280.

As shown in FIG. 6, the header part is related to an address such as a source IP, a destination IP (private IP), a port, and the like. This is configured by obtaining mapping information of the ProxyAgentMIB of FIG. 5 and MappingMIB of FIG. 2. As described above, since the header part of the SNMP PDU includes information on private IP, the present invention enables connection processing between a network composed of a public IP network and a private IP network. Also, the header part may have an OID value (proxyObjectEntry) and may also include an Index value of the proxyObjectEntry.

FIG. 7 is a detailed schematic process diagram of the proxy processing unit 260 and the SNMP transmission / reception processing unit 250 in the management protocol agent 240 of FIG. 2.

The management protocol agent 240 receives the Recv PDU from the SNMP Recv Process 710 and separates the ProxyHeader (Header) and the ProxyBodyPDU (Body) from 720. After extracting the source IP, Port, Dest IP, Port from the header section and stores in the queue (750), and extracts the private IP address. Thereafter, the body unit is transmitted to the smart grid device 700 corresponding to the private IP address (740). The smart grid device 700 transmits a response to the management protocol agent 240, and the management protocol agent 240 transmits the received information and the Dest IP, Port, and Source IP stored in the queue 750. In operation 790, the port information is obtained and a new PDU is created and transmitted to the management protocol manager 200.

8 is a diagram of an overall process according to the present invention.

The SNMP manager generates a body part of the PDU having management information (MIB) of the smart grid device (820). Thereafter, proxy information (private IP information, port information, etc.) is received from a database to generate a header part of the PDU (800, 802, 822). The generated PDU (Proxy-SNMP PDU) is transmitted to the proxy device (management protocol agent) (840). The proxy device divides the received PDU into a header and a body (842). The header part is stored in a queue (845) and the body part is transmitted to a smart grid device having a private IP (860). The smart grid device processes according to the received message and transmits a response to the proxy device (862). Thereafter, the proxy device regenerates the PDU by adding the received message and the information stored in the queue (848) and transmits the PDU to the SNMP manager (826).

As such, the PDU may manage a smart grid communication network in which a public IP network and a private IP network are mixed, including private IP information.

As mentioned above, although the present invention has been described with reference to the drawings, it will be understood by those skilled in the art that the present invention is not limited to the above description and can be changed and modified in various ways without departing from the spirit and scope of the present invention. Accordingly, the invention is limited only by the claims and equivalents described below.

Claims (11)

A management protocol (SNMP) manager that generates a protocol data unit (PDU),
A management protocol (SNMP) agent receiving the protocol data unit, and
A smart grid network management system comprising a device for a smart grid having a private IP address,
The protocol data unit includes the private IP address information,
The protocol data unit has a header portion and a body portion,
The header portion of the protocol data unit is
The smart grid communication network management system having a private IP network, characterized in that it comprises IP address information and port information of the management protocol manager. The method according to claim 1,
The private IP address information is included in the header portion, smart grid communication network management system having a private IP network. The method according to claim 1,
The private IP address information is stored in the management protocol manager and the management protocol agent, smart grid communication network management system having a private IP network. The method according to claim 1,
The management protocol manager,
The common management information overlaps among the management information bases (MIBs) of the devices for the smart grid and the individual management information (PrivateMIB) according to the devices for each smart grid, and stores the common management information and the individual. A smart grid communication network management system having a private IP network, characterized in that it comprises a database for storing the Object Identifier (OID) value of each device for the smart grid mapped to the management information. The method according to claim 2,
And the header part of the protocol data unit further comprises an object identifier value mapped to management information of the devices for the smart grid. delete The method according to claim 2,
The body portion of the protocol data unit,
Smart grid communication network management system having a private IP network, characterized in that it comprises management information of the device for the smart grid. The method according to claim 2,
The management protocol agent,
And a parsing processing unit which separates a header part and a body part of the protocol data unit and stores the header part in a queue. 10. The smart grid communication network management system having a private IP network. The method according to any one of claims 1 to 5, 7 and 8,
The management protocol agent is a proxy server (Proxy Server), characterized in that the smart grid communication network management system having a private IP network. The protocol data unit having a header portion including an IP address of a management protocol manager, a private IP address of a device for a smart grid, and an object identifier of the device for the smart grid, and a body portion including management information of the device for the smart grid; Receiving from a protocol manager;
Separating and storing the header portion of the received protocol data unit in a queue;
Sending the body portion of the received protocol data unit to a device for a smart grid having the private IP address;
Receiving a response from the device for a smart grid having the private IP address; And
Generating a protocol data unit including the received response information and the IP address of the management protocol manager stored in the queue and transmitting the generated protocol data unit to the management protocol manager;
Smart grid communication network management method having a private IP network, including. delete

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