KR20040056383A - Method and Apparatus for Permitting Loopback in Junction of Ethernet and SDH/SONET - Google Patents

Abstract

PURPOSE: An apparatus and a method for allowing loopback at a junction of Ethernet and SDH(Synchronous Digital Hierarchy)/SONET(Synchronous Optical Network) are provided to simply develop an NG-SDH/SONET equipment by removing a loopback problem arising when a shared virtual channel is used. CONSTITUTION: An NG-ADM(Add Drop Mux) extracts an Ethernet packet from channel data received through a line card(S700). The NG-ADM determines a destination address of the extracted Ethernet packet(S702). If the destination address of the Ethernet packet is directed to an Internet network(S704), the NG-ADM transmits the Ethernet packet through the Internet network(S706). If the destination address of the Ethernet packet is directed to internal network(S708), the NG-ADM transmits the Ethernet packet to a corresponding terminal through the line card(S710).

Description

Apparatus and method for allowing loopback at the junction between Ethernet and SDH / SOONET {Method and Apparatus for Permitting Loopback in Junction of Ethernet and SDH / SONET}

The present invention relates to an apparatus and method for allowing loopback at an Ethernet-SDH / SONET junction that allows loopback of Ethernet packets occurring at an Ethernet-SDH / SONET junction.

Synchronous Digital Hierarchy (SDH) is a standard technology for synchronous data transmission on optical media and is internationally equivalent to Synchronous Optical Network (SONET). Both technologies are faster and less expensive to access networks than traditional PDH (Plesiochronous Digital Hierarchy) equipment.

In digital telephone transmission, "synchronous" means that bits belonging to one call all move in one transmission frame. "Plesiochronous" means a call that is nearly synchronous or that one call must be extracted from one or more transmission frames.

Hereinafter, a network using the SDH / SONET as described above will be described.

1 is a view showing the configuration of a conventional network, Figure 2 is a diagram showing a protocol stack of a conventional TDM-based SDH / SONET.

Referring to FIG. 1, a network is largely divided into an ATM backbone 160 and an IP backbone 140, and the IP backbone 140 is a concept of the Internet that we commonly hear.

In the core (access) or access to the user section is composed of an SDH / SONET ring, each branch point of the ADM (Add Drop Mux) (120, 125) type of equipment exists. The user stage 100 has a small SOHO router (110) is in charge of the interface with the ADM equipment 120.

Looking at each step by interface, between the user 100 and SOHO router 110 is connected by Ethernet, PDH from SOHO router 110 to ADM 120, SDH / SONET between ADM (120, 125), The parent is either SDH / SONET-based ATM or IP.

However, with the development of the Internet in recent years, as the use of IP / Ethernet has increased rapidly, more and more IPs have been carried on the underlying SDH / SONET. By the way, the application is not directly loaded on the SDH / SONET, the application is inefficient because it has a complex structure of IP / PPP / ATM / SDH / SONET as shown in FIG. In other words, the TDM-based SDH / SONET protocol stacks voice and data signals (IP) on one optical beam and allocates different channels to perform communication.

Of course, the structure of SDH / SONET was also inefficient for applying various features of IP recently required. For this reason, a way of carrying Ethernet directly over SDH / SONET network was devised, which is EOS.

Hereinafter, a network in which EOS is added in a TDM-based network will be described with reference to FIG. 3.

3 is a diagram showing the structure of a network when adding EOS in a conventional TDM-based network.

Referring to FIG. 3, NG-ADMs 320 and 325 include Ethernet ports.

The Ethernet port is connected to LAN switches 315 to allow multiple terminals 300 to use one channel.

4 is a view showing the structure of the EOS protocol.

Referring to FIG. 4, Ethernet and IP data are accumulated on the SDH / SONET, and other channels are allocated to communicate with each other.

FIG. 5 is a diagram schematically illustrating a configuration of a loopback control device in an Ethernet port of a conventional NG-ADM.

Referring to FIG. 5, the loopback removal apparatus in the Ethernet port of the NG-ADM includes a TDM cross connector 510, an EOS unit 520, and an Ethernet switch 530.

The TDM cross connector 510 switches each channel data of SDH / SONET transmitted from each line card 500 to a destination port.

The EOS unit 520 extracts or inserts an Ethernet packet from channel data transmitted from the TDM cross connector 510.

The Ethernet switch 530 processes the interface of the EOS unit 520 and other additional Ethernet interfaces. That is, the Ethernet switch 530 transmits the Ethernet packet transmitted from the EOS unit 520 through the Internet network.

Hereinafter, the operation of the loopback removal apparatus in the Ethernet port of the NG-ADM configured as described above will be described.

Channel data transmitted from each line card 500 is transmitted to the TDM cross connector 510, and the TDM cross connector 510 transmits the transmitted channel data to the EOS unit 520.

The EOS unit 520 extracts an Ethernet packet from the transmitted channel data and transmits it to the Ethernet switch 530. Then, the Ethernet switch 530 transmits the transmitted Ethernet packet through the Internet network. In this case, if the channel data is not a packet going to the Internet network, but is a packet going back to the internal network, the packet is transmitted to the TDM cross connector 510 again through the EOS port 520 through the same port of the Ethernet switch 530. do.

From the standpoint of Ethernet switch 530, there is a contradictory situation in which packets sent to a specific port need to be sent back to the same port. In the case of an actual Ethernet network, such a case does not occur, so the channel data is dropped.

However, if you use a dedicated virtual channel when operating the conventional EOS as described above, there is no problem because there is one-to-one communication, but when using a shared virtual channel, whether to drop or pass all Ethernet packets in the EOS channel for each EOS interface Decide However, since EOS does not have such a rule, all packets have to make a determination after going through EOS to the upper Ethernet switch or controller.

In addition, a loopback problem occurs in which an Ethernet packet is returned to the MAC interface, so that Internet service is available, but EOS using a shared virtual channel has a problem in one-to-one leased line communication.

Accordingly, an object of the present invention is to provide an apparatus and method for allowing loopback at the junction of SDH / SONET that can easily develop NG-SDH / SONET equipment by eliminating the loopback problem that occurs when using a shared virtual channel.

1 is a view showing the configuration of a conventional network.

2 is a diagram illustrating a protocol stack of a conventional TDM-based SDH / SONET.

3 is a diagram showing the structure of a network when adding EOS in a conventional TDM-based network.

4 illustrates the structure of an EOS protocol.

5 is a diagram schematically showing the configuration of a loopback control device in the Ethernet port of the conventional NG-ADM.

6 is a view schematically showing the configuration of the NG-ADM according to an embodiment of the present invention.

7 is a flowchart illustrating a method for allowing loopback in an Ethernet port according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

110: SOHO router 120, 125: ADM

130, 330: Router 140, 340: IP backbone

150, 350: ATM switch 160, 360: ATM backbone

315: LAN switch 320, 325: NG-ADM

500, 600: Line card 510, 610: TDM cross connector

520, 620: EOS 530, 640: Ethernet switch

630: loopback part

According to an aspect of the present invention to achieve the above object, TDM cross connector for switching the channel data transmitted from the line card to the destination port, EOS unit for extracting or inserting the Ethernet packet from the channel data transmitted from the TDM cross connector And a loopback unit for determining and transmitting a destination address of the Ethernet packet transmitted from the EOS unit, and an Ethernet switch for transmitting the Ethernet packet transmitted from the loopback unit to the Internet network. In the loopback allowance device is provided.

The loopback unit determines whether the destination address of the Ethernet packet is in the direction of the Internet network or the direction of the internal network. If the destination address of the Ethernet packet is in the direction of the Internet network, the loopback unit transmits the Ethernet packet to the Ethernet switch. .

The operation of the loopback unit is performed in at least one of the EOS unit and the Ethernet switch.

According to another aspect of the present invention, the Ethernet packet is extracted from the channel data received through the line card, and the destination address of the extracted Ethernet packet is determined. If the Ethernet packet is transmitted through the Internet network and the destination address of the Ethernet packet is in the direction of the internal network, the Ethernet packet is transmitted to the corresponding terminal through a line card.

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

FIG. 6 is a diagram schematically illustrating a configuration of a loopback removal apparatus in an Ethernet port of an NG-ADM according to an embodiment of the present invention.

Referring to FIG. 6, the loopback removal apparatus in the Ethernet port of the NG-ADM includes a TDM cross connector 610, an EOS unit 620, a loopback unit 630, and an Ethernet switch 640.

The TDM cross connector 610 switches the channel data of the SDH / SONET transmitted from each line card 600 to the destination port.

The EOS unit 620 extracts or inserts an Ethernet packet from channel data transmitted from the TDM cross connector 610.

The loopback unit 630 determines whether the destination address of the Ethernet packet transmitted from the EOS unit 620 is the Internet direction or the internal network direction.

As a result of the determination, if the destination address of the Ethernet packet is the Internet direction, the loopback unit 630 transmits the transmitted Ethernet packet to the Ethernet switch 640.

If the result of the determination is that the destination address of the Ethernet packet is in the direction of the internal network, the loopback unit 630 transmits the transmitted Ethernet packet to the EOS unit 620.

As described above, the loopback unit 630 switches channel data going to an address different from the input address to the Ethernet switch 640, and returns channel data going to the same address as the input port to the EOS unit 620 again.

The Ethernet switch 640 processes the interface of the EOS unit 620 and other additional Ethernet interfaces. That is, the Ethernet switch 640 transmits the Ethernet packet transmitted from the EOS unit 620 through the Internet network.

Hereinafter, the operation of the loopback removal apparatus in the Ethernet port of the NG-ADM configured as described above will be described.

Channel data transmitted from each line card 600 is transmitted to the TDM cross connector 610, and the TDM cross connector 610 transmits the transmitted channel data to the EOS unit 620. The EOS unit 620 extracts an Ethernet packet from the transmitted channel data and transmits it to the loopback unit 630.

The loopback unit 630 determines whether the destination address of the Ethernet packet transmitted from the EOS unit 620 is the Internet direction or the internal network direction.

As a result of the determination, if the destination address of the Ethernet packet is the Internet direction, the loopback unit 630 transmits the transmitted Ethernet packet to the Ethernet switch 640.

Then, the Ethernet switch 640 transmits the transmitted Ethernet packet through the Internet network. If the result of the determination is that the destination address of the Ethernet packet is in the direction of the internal network, the loopback unit 630 transmits the transmitted Ethernet packet to the EOS unit 620. Then, the EOS unit 620 transmits the transmitted Ethernet packet to the corresponding line card 600 through the TDM cross connector 610.

According to another embodiment of the present invention, the loopback part may be inserted into an Ethernet switch or an EOS part.

7 is a flowchart illustrating a method for allowing loopback in an Ethernet port according to an embodiment of the present invention.

Referring to FIG. 7, the NG-ADM extracts an Ethernet packet from channel data received through a line card (S700). The NG-ADM then determines a destination address of the extracted Ethernet packet (S702).

If the destination address of the Ethernet packet is the Internet network direction (S704), the NG-ADM transmits the Ethernet packet through the Internet network (S706).

If the destination address of the Ethernet packet is the internal network direction (S708), the NG-ADM transmits the Ethernet packet to the corresponding terminal through a line card (S710).

The present invention is not limited to the above embodiments, and many variations are possible by those skilled in the art within the spirit of the present invention.

As described above, according to the present invention, it is possible to provide an apparatus and method for allowing loopback at a junction between Ethernet and SDH / SONET, which enables one-to-many communication of EOS to NG-SDH / SONET type equipment.

In addition, according to the present invention, it is possible to provide an apparatus and method for allowing loopback at the junction of Ethernet and SDH / SONET that can easily develop NG-SDH / SONET equipment by eliminating the loopback problem that occurs when using a shared virtual channel. .

Claims (5)

A TDM cross connector for switching channel data transmitted from the line card to a destination port; An EOS unit for extracting or inserting an Ethernet packet from channel data transmitted from the TDM cross connector; A loopback unit for determining and transmitting a destination address of the Ethernet packet transmitted from the EOS unit; and Ethernet switch for transmitting the Ethernet packet transmitted from the loopback part to the internet network Loopback allow device at the junction of Ethernet and SDH / SONET, characterized in that it comprises a. The method of claim 1, The loopback unit determines whether the destination address of the Ethernet packet is the Internet direction or the internal network direction, and transmits the Ethernet packet to the Ethernet switch if the destination address of the Ethernet packet is the Internet network. Device for allowing loopback at the junction of Ethernet and SDH / SONET. The method of claim 1, Operation of the loopback unit is performed in at least one of the EOS unit and the Ethernet switch loopback allow apparatus at the junction of Ethernet and SDH / SONET. Extracting an Ethernet packet from the channel data received through the line card; Determining a destination address of the extracted Ethernet packet; If the destination address of the Ethernet packet is directed to the Internet network, transmitting the Ethernet packet through the Internet network Loopback allow method at the junction of Ethernet and SDH / SONET, characterized in that it comprises a. The method of claim 4, wherein And if the destination address of the Ethernet packet is in the direction of the internal network, transmitting the Ethernet packet to the corresponding terminal through a line card.