KR101619511B1 - Device for Packet Transport Network setting network band using LLDP and method for constructing Control Plane Network - Google Patents

Abstract

A method for constructing a control plane network for a packet transport network according to the present invention is a method for setting a network band of a packet transport network, comprising: setting private IP addresses of respective linked nodes, and performing communications between the individual nodes by using the private IP addresses. The network band is automatically set through a method for generating unique private IP addresses using MAC addresses between adjacent nodes, in which a link layer discovery protocol (LLDP) protocol data unit (PDU) is used. According to the above-described configuration of the present invention, even a mesh network-type network does not require particular attention in setting a unique network band.

Description

TECHNICAL FIELD [0001] The present invention relates to a packet transmission network for establishing a unique network band using a link layer search protocol, and a method for constructing a control plane network using the same,

The present invention relates to a packet transmission network for establishing a unique network band using LLDP and a method for constructing a control plane network using the same. More particularly, the present invention relates to a packet transmission network in which, in managing a network band allocated to each link in a packet transmission network (PTN) As the number increases and the link changes to a more complex mesh network, much attention and effort needs to be paid to setting up a unique network bandwidth, so that each link or node has a unique MAC address, To the IP address to automatically set the unique network bandwidth of each node, and the MAC address information between neighboring nodes can be easily acquired using the standardized LLDP, so that the private IP network can be constructed only by setting the LLDP And a method for constructing a control plane network of a packet transmission network.

In general, as the number of users of Internet contents increases, quality of service, such as download speed of Web download, video, audio, image, application, etc., becomes a problem.

In order to solve these problems, a variety of contents transmission service technologies have been developed recently. With such contents transmission service, large-capacity file transmission such as online video (VoD, live streaming), music streaming, file uploading and file downloading becomes possible, The market is also expanding accordingly.

In recent years, along with the proliferation of smart phones, services for delivering large-volume contents such as You Tube, IPTV, Apple appstore, and T-Store have been developed. Traffic of the communication network is rapidly increasing due to the emergence of such services.

However, as the number of nodes in the packet transport network increases and traffic to be processed by each node surges, more care and management is required in operating the packet transport network.

Korean Patent Laid-Open No. 10-2008-0113793

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a packet transmission network in which a unique network bandwidth is set even if the number of nodes belonging to a control plane responsible for a control packet increases, And to provide a method for constructing a control plane network.

It is another object of the present invention to provide a packet transmission network and a method of establishing a control plane network in which a specific network bandwidth can be set only by setting LLDP.

According to an aspect of the present invention, there is provided a network management system including an EMS for network management, a GNE for transmitting data according to control of the EMS, and a plurality of NEs connected to the GNE, Wherein the EMS includes a public IP network in which the EMS is connected to the GNE and a private IP network to which a plurality of the NEs are linked, The network is connected to the GNE / NE, and is connected to the plurality of NEs through the private IP network. The NEs automatically generate the private IP to establish a packet transmission network.

According to another aspect of the present invention, a method of constructing a control plane network includes transmitting and receiving a message between adjacent nodes, obtaining MAC address information in the message, setting a private IP of each node using the MAC address, , And performs communication between the nodes using the private IP.

As described above, according to the configuration of the present invention, the following effects can be expected.

First, there is no need for separate management for the packet transmission network, and it is expected that a unique L3 private IP network can be constructed by simply setting LLDP in the port to which the link is connected.

Second, even a complex mesh network type network requires no special attention to the network bandwidth setting, thus enhancing operator convenience.

1 is a block diagram showing the configuration of a packet transmission network according to the present invention;
2A to 2C illustrate an example of converting an MAC address into an IP address according to the present invention.
3 is a block diagram showing a basic operation of LLDP according to the present invention;
4 is a block diagram illustrating a node module structure for network construction according to the present invention;
5 is an example of an LLDP PDU frame format according to the present invention.

Brief Description of the Drawings The advantages and features of the present invention, and how to achieve them, will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Is provided to fully convey the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. The dimensions and relative sizes of layers and regions in the figures may be exaggerated for clarity of illustration. Like reference numerals refer to like elements throughout the specification.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a packet transmission network for setting a unique network bandwidth using the LLDP according to the present invention will be described in detail with reference to the accompanying drawings.

The Packet Transport Network (PTN) of the present invention relates to a network providing various types of wired and wireless services such as voice and data in a single communication network. It is effective for packet transmission requiring high bandwidth such as high image quality and multimedia service because it is able to easily manage and control the bandwidth such as packet capacity or speed with software control without line extension.

Referring to FIG. 1, the packet transmission network PTN of the present invention includes an element management system (EMS) 110 for managing a network, and a GNE 110 for transmitting data signals according to a control signal of the EMS 110 in a point- A plurality of network elements 130 connected to the GNE 120 in a ring-type, line-type, or star-type manner to set a network band, .

The packet transmission network PTN includes a public IP network in which the EMS 110 is networked with the NE 130 and a private IP network to which a plurality of NEs 130 are linked, GNE 120 / NE 130, and is network-connected to a plurality of NEs 130 through a private IP network. As described above, the plurality of NEs 130 can be operated with a private IP. The present invention can automatically generate a private IP using the MAC address of the neighboring node.

The GNE 120 functions as a gateway server connecting the EMS 110 and the plurality of NEs 130. Collects network management operation information of a plurality of NEs 130 and transmits them to the EMS 110. When a message delivery request is received from the EMS 110, the network management operation information is analyzed and transmitted to the NEs 130 do.

The GNE 120 may include a public IP port connected to an external network and a private IP port connected to a plurality of NEs. Since public IP resources are limited, a plurality of NEs 130 may receive a private IP . However, as the number of NEs 130 becomes too large, a certain failure may occur in generating and assigning private IPs.

A packet transmission network (PTN) is divided into a control plane (Control Plane) responsible for control packets and a data plane (Data Plane) responsible for data packets.

An IP control packet is exchanged between the NEs 130 through a control plane and an IP control packet used for a packet transmission network PTN includes an in-band DCC (Data Communication Channel) and an MPLS signaling protocol (RSVP, LDP) . The present invention uses a private IP network as a part of building a control plane network for delivering IP control packets.

And transmits and receives user data packets of MPLS (Multi Protocol Label Switching) type through the data plane between the NEs 130.

Referring to FIG. 2A, since links of respective nodes have a unique MAC address, the present invention proposes a method of automatically setting a unique network band using the link. For example, the MAC address (00: 11: F4: 17: 34: 58) includes the 3Byte (00: 11: F4) including the band code (Vendor code) 58).

At this time, the private IP of the present invention includes a network ID 30 bit including at least the last 24 bits of the MAC address and a lower 2-bit host ID. Such a network ID and a host ID are combined to generate a private IP address. This allows you to set your own IP network address.

In particular, each node creates a private IP address by mapping the lower 24 bits based on the lower MAC address, in contrast to the MAC address of the peer port to be connected to the local port at both ends of the link.

Referring to FIG. 2B, a case where a 10.0.0.1 private IP band designated differently from FIG. 2A is used will be described.

At this time, the private IP of the present invention includes 31 bits of network ID including at least the last 23 bits of the MAC address and a lower 1 bit host ID. Such a network ID and a host ID are combined to generate a private IP address. This allows you to set your own IP network address.

In particular, each node creates a private IP address by mapping the lower 23 bits based on the lower MAC address, in contrast to the MAC address of the peer port to be connected to the local port at both ends of the link.

Referring to FIG. 2C, unlike FIG. 2A, a case where a MAC address is used uniquely for each node other than a link will be described.

At this time, the private IP of the present invention includes 31 bits of network ID including 7 bits for distinguishing at least the last 16 bits of the MAC address and 127 of each link, and a lower 1 bit host ID. Such a network ID and a host ID are combined to generate a private IP address. This allows you to set your own IP network address.

In particular, each node generates a private IP address by mapping the lower 16 bits based on the lower MAC address, in comparison with the MAC address of the peer port to be connected to the local port at both ends of the link.

The L3 interfaces are configured as an L3 network through a routing protocol (OSPF, ISIS), and communication between the nodes can be performed by a routing table.

Referring to FIG. 3, a link layer discovery protocol (LLDP) (IEEE Std 802.1AB) is used to determine a MAC address between communication links. That is, the NE 130 uses the link layer search protocol (LLDP), which is already standardized, in order to receive the message of neighboring nodes and obtain MAC address information in the message.

Referring to FIG. 4, each node includes a line card including an LLDP PDU transmission / reception module for exchanging LLDP PDUs from a device, and a control unit (Control) including an IP generation module for converting a MAC address into a private IP address. Unit). The control unit converts the private IP address generated by the IP generation module, and the generated private IP address is set by the L3 interface management module, and the private IP network can be established by the L3 routing module (OSPF).

5, a link layer search protocol (LLDP) transmits a protocol data unit (PDU), transmits its link information to a neighbor node, and stores the type, length, value, (TLV) message to exchange various information other than the MAC address.

For example, the PDU of the link layer search protocol (LLDP) includes a TLV in addition to the MAC address. The TLV may include a Classis ID, a Port ID, a System Name, a System Description, System Capabilities, a Management Address, and the like.

- Chassis ID: 00: 11: F4: 17: 34: 57 ← MAC address of the corresponding port

- Port ID: S01-P2 ← PID

- TTL: 1

- System Name: COT1 ← TID

- System Description: WOORINET ← vendor

- System Capabilities: Router

- Management Address: 192.168.12.1 ← L3 network interface address

Hereinafter, a method of constructing a control plane network for setting a unique network band using a link layer search protocol (LLDP) in a packet transmission network (PTN) will be described.

A method of constructing a control plane network according to the present invention includes: transmitting and receiving a message between adjacent nodes (S10); acquiring MAC address information in the message (S20); setting a private IP of each node using the MAC address (S30), and performing communication between each node using the private IP (S40).

For example, in a network bandwidth setting method of a packet transmission network that sets up private IPs of nodes linked to each other and performs communication between the nodes, the method includes: generating a unique private IP using a MAC address between adjacent nodes, And the band is automatically set.

To obtain MAC address information between adjacent nodes, LLDP is used. Referring again to FIG. 3, the LLDP transmits its own link information to the neighboring node by transmitting the PDU every 5 seconds.

As described above, according to the present invention, a MAC address of a magnetic port is compared with a MAC address of an opposite port to be connected, and a lower 3-byte is mapped based on a lower MAC address to generate a private IP, Is a technical idea. Many other modifications will be possible to those skilled in the art, within the scope of the basic technical idea of the present invention.

100: packet transmission network 110: EMS
120: GNE 130: NE

Claims (10)

A packet forwarding network including an EMS for network management, a GNE for transmitting data according to the control of the EMS, and a plurality of NEs connected to the GNE for setting a network band,
Wherein the packet transfer network includes a public IP network in which the EMS is connected to the GNE and a private IP network to which a plurality of the NEs are linked, the EMS is network-connected to the GNE / NE through the public IP network, The plurality of NEs are connected to the network through the private IP network, the NEs automatically construct the private IP to establish a control plane network,
The NEs automatically generate the private IP using the MAC address of the neighboring node, transmit the MAC address of the local port, receive the MAC address of the peer port to be connected, And generates the private IP address based on the lower MAC address,
Wherein the private IP includes a MAC address of the NEs,
The MAC address includes a 3-byte field including a band code and a 3-byte field including a unique address,
The private IP includes a combination of a network ID 30 bit including at least the last 24 bits of the MAC address and a host ID of a lower 2 bits,
The MAC address is obtained using a link layer discovery protocol (LLDP) packet, and the LLDP packet is transmitted to the MAC layer by using a Type, a Length, and a Value (TLV) Acquire information together,
In this case, the private IP address uses both the MAC address and the TLV message. The TLV message includes a System Name, a System Description, a System Capabilities, and a Management Address Address). delete delete Sending and receiving messages between adjacent nodes;
Obtaining MAC address information from the message;
Setting a private IP of each node using the MAC address; And
And performing communication between the nodes using the private IP,
Using the LLDP to obtain the MAC address information between the neighboring nodes,
The private IP includes a network ID 30 bit including at least the last 24 bits of the MAC address and a lower 2-bit host ID,
The LLDP transmits its own link information to a neighboring node by transmitting and receiving a PDU every 5 seconds,
The LLDP PDU includes a Type, a Length, and a Value (TLV) in addition to the MAC address,
Wherein the TLV includes a system name, a system description, a system capability, and a management address. delete delete delete delete A method for establishing a control plane network of a packet transfer network for establishing a private IP of each linked node and performing communication between the nodes using the private IP,
The network bandwidth is automatically set by generating a unique private IP using the MAC address between adjacent nodes, but using the LLDP PDU,
The LLDP PDU includes a Type, a Length, and a Value (TLV) in addition to the MAC address,
The MAC address includes a 3-byte including a band code and a backward 3-byte including a unique address. The private IP includes a network ID 30 bit including at least the last 24 bits of the MAC address, a lower 2-bit host (Host) ID,
Wherein the TLV includes a system name, a system description, a system capability, and a management address. delete

Images