KR20020069464A - Routing system for sdh transmission system capable of a plural sdh traffic - Google Patents

Abstract

PURPOSE: A routing system for an SDH(Synchronous Digital Hierarchy) transmission system for accommodating a plurality of SDH traffics is provided to efficiently guide network management and improve the routing performance of an internal portion of a system by composing one routing module having one network address in one system. CONSTITUTION: A plurality of DCC(Data Communication Channel) devices are separated according to SDHs, and correspond and connect to lower SDH systems by each SDH, respectively for providing a data communication through a DCC. A plurality of broadcast conversion modules(302,304,306) correspond to the number of uniform DCC devices according to the SDH. A routing module(308) connects to the broadcast conversion modules(302,304,306) by a LAN(Local Area Network), and connects to an SDH system of an other node by the DCC. A virtual LAN device classifies several virtual LAN MAC(Media Access Control) addresses to correspond to the broadcast conversion modules(302,304,306) and connects the classified virtual LAN MAC(Media Access Control) addresses to the routing module(308).

Description

Routing system for a synchronous digital hierarchy transmission system that accepts a large number of synchronous digital hierarchy traffics {ROUTING SYSTEM FOR SDH TRANSMISSION SYSTEM CAPABLE OF A PLURAL SDH TRAFFIC}

The present invention relates to an SDH transmission system that accommodates a plurality of synchronous digital hierarchy (SDH) traffic, and more particularly, to an Open Systems Interconnection (ISI) Intermediate System-Intermediate System (IS-IS) protocol. It relates to a system for performing network routing using.

1 shows an example of a typical routing system employed in an SDH transmission system that accommodates a large number of SDH traffic. 1 shows a plurality of 155 Mbps SDH transmission systems (hereinafter referred to as "155M systems") (nodes A1 to A8, nodes B1 to B8) and a number of 622 Mbps SDH transmission systems (hereinafter referred to as "622M systems") (nodes C1 to C4). ) To configure multiple routing modules 104-110 in a 10G system 100 connected to other SDH 10Gbps systems (hereinafter referred to as "10G systems") 102 connected to other SDH 10Gbps systems (hereinafter referred to as "10G systems"). All. As shown in FIG. 1, data communication with a transmission system of various levels of traffic is physically divided into boards and self units for each level to accommodate a DCC (Data Communication Channel) channel. Area Network). Data through 155M systems (nodes A1-A8, nodes B1-B8), 622M systems (nodes C1-C4), and DCC channels (DCC_A1-DCC_A8, DCC_B1-DCC_B8, DCC_C1-DCC_C4) of the 10G system 102 at each level. Routing modules 104-110 for communication are different network addresses (e.g., NSAP_155A for routing module 104, NSAP_155B for routing module 106, NSAP_622 for routing module 108, routing module 108). 110 operates with NSAP_10G as if it exists inside other systems, and they are connected to the LAN inside the system and interoperate with each other with the LAN IS-IS routing protocol.

Another example of a typical routing system employed in an SDH transmission system accommodating a plurality of SDH traffic is shown in FIG. FIG. 2 shows DCC channels (DCC_A1 to DCC_A8, DCC_B1 to DC_B8, DCC_C1 to DCC_C4) that are physically separated from one routing module 202 in the 10G system 200, as if they are physically in the same place through the LAN. This is an example of introducing a pseudo concept to recognize the channel. That is, each of the DCC channels DCC_A1 to DCC_A8, DCC_B1 to DCC_B8, and DCC_C1 to DCC_C4 is recognized as one subnetwork of the routing module 202.

However, the biggest problem in the case of FIG. 1 described above is that more than one network address exists in one system. That is, it can be recognized that there are several systems in the network instead of one system. This is a factor that reduces the efficiency of network management. In addition, in terms of network management, an operator must recognize that multiple networks exist for a system and maintain duplicate network addresses. It also degrades routing performance inside the system.

In the case of FIG. 2, the DCC channels of a predetermined number or more cannot be accommodated in consideration of hardware performance and the maximum number of subnetworks of the routing module.

Accordingly, an object of the present invention is to provide a routing system that can have only one network address and routing module in one system, thereby improving network management efficiency and routing performance within the system.

1 illustrates an example of configuring a plurality of routing modules in a 10Gbps SDH system that accommodates a plurality of SDH traffics.

FIG. 2 is a diagram illustrating an example of configuring a single routing module employing a pseudo concept in a 10Gbps SDH system that accommodates a plurality of SDH traffics. FIG.

3 is a diagram illustrating an example in which a routing module is configured by adopting a broadcast concept for point-to-point communication in a 10Gbps SDH system that accommodates a plurality of SDH traffics according to an embodiment of the present invention;

4 and 5 illustrate the operation of FIG. 3 according to an embodiment of the present invention.

The routing system of the present invention for achieving the above object introduces the concept of broadcast in point-to-point communication, and there is a problem that one or more network addresses exist in a conventional system and system internal routing. It solves the problem of performance degradation.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description and the annexed drawings, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

FIG. 3 illustrates an example in which one routing module is configured by adopting a broadcast concept for point-to-point communication in a 10Gbps SDH system accommodating a plurality of SDH traffic according to an embodiment of the present invention. Instead of the module in charge of routing for each level, the 10G system 300 implements the broadcast switching modules 302 to 306 that convert point-to-point communication such as DCC communication into broadcast communication such as LAN. The broadcast switching module (302 to 306) knows the network address of the system directly connected to the DCC channel in a hello packet received through each of the DCC channels (DCC_A1 to DCC_A8, DCC_B1 to DCC_B8, DCC_C1 to DCC_C4). It has a table that stores and stores it, that is, a table comprising a DCC channel number, an NSAP address, and a virtual LAN MAC (Media Access Control) address. Accordingly, the routing system of FIG. 3 as shown in FIG. 4 (a) operates as if it has a physical configuration as shown in FIG. 4 (b).

That is, the present invention separates the internal LAN of the system as shown in FIG. 1 to be recognized differently as if they are physically one LAN like each of MAC_A, MAC_B, and MAC_C of FIG. That is, the LAN MAC addresses of the hardware where the routing module 308 is physically divided are divided as if there are three virtual LANs, namely, LAN_A-MAC_A, LAN_B-MAC_B, and LAN_C-MAC_C. Of course, LAN_A-LAN_B-LAN_C is implemented to prevent communication through the LAN. Accordingly, the system as shown in FIG. 5 (a) is recognized differently as shown in FIG. 5 (b).

Now, the operation for routing according to FIG. 3 will be described in detail. For example, for the 155M system of node A1, point-to-point communication is performed with the 155M system (node A1) via DCC_A1 of the broadcast switching module 302 in charge of the 155M SDH. The broadcast switching module 302 first obtains the network address of node A1 from the hello packet of node A1. The virtual LAN MAC address mapped to the DCC channel DCC_A1 is obtained. This is stored in a table [DCC channel number, NSAP address, virtual LAN MAC address (MAC_A1)]. Next, this point-to-point format data is converted into broadcaster format data having a virtual LAN MAC address mapped to the corresponding DCC channel (DCC_A1), and transferred to the destination MAC address MAC_A, which is finally routed to the module 308. To arrive. From the perspective of the routing module 308, the 155M systems of nodes A1-A8 are connected to the LAN via LAN_A. Nodes A1 through A8 operate in the same manner as described above via the broadcast switching module 302. In addition, the 155M system of the nodes B1 to B8 and the 622M system of the nodes C1 to C4 operate in the same manner as the node A1 and the broadcast switching module 302 through corresponding broadcast switching modules 304 and 306, respectively.

On the other hand, when routing module 308 receives a message to be delivered via node A1, routing module 308 sends MAC_A1 to the destination MAC address on the LAN_A subnetwork. This message arrives at the broadcast switching module 302. Then, the broadcast switching module 302 finds the DCC channel (DCC_A1) corresponding to MAC_A1 in the conversion table and converts the received message into point-to-point data and transmits the data to the node A1's 155M system on DCC_A1.

Therefore, by using virtual LAN communication, the number of sub-networks of the routing module is significantly reduced, so that one routing module having one network address exists in one system, effectively inducing network management and improving routing performance inside the system. You can. In addition, since only one routing module exists, only one routing protocol stack is needed without requiring multiple routing protocol stacks.

Meanwhile, in the above description of the present invention, specific embodiments have been described, but various modifications can be made without departing from the scope of the present invention. In particular, in the embodiment of the present invention has been given an example of accommodating SDH traffic of 155M and 622M, the same applies to the case where the type and number of hierarchy is different. Therefore, the scope of the invention should not be defined by the described embodiments, but should be defined by the equivalent of claims and claims.

As described above, the present invention solves the problem of having one or more network addresses by having one routing module having one network address in one system and solving the problem of deterioration of routing performance due to the presence of several modules. Can be derived efficiently and the routing performance inside the system can be improved. In addition, the cost savings of using the protocol stack can be achieved by requiring only one routing protocol stack.

Claims (2)

In the SDH transmission system that accommodates a large number of SDH traffic, A plurality of DCC devices which are separated by SDH and connected to each SDH system one by one to a predetermined number of lower SDH systems to provide data communication through a DCC channel, A plurality of broadcast switching modules each corresponding to a predetermined number of the DCC devices for each SDH; A routing module connected to the broadcast switching modules via a LAN and connected to the SDH system of another node through a DCC channel; And a virtual LAN means for classifying a plurality of virtual LAN MAC addresses corresponding to the broadcast switching modules and connecting the routing module with respect to one LAN. The method of claim 1, The broadcast switching module converts the point-to-point data received through the corresponding DCC device into broadcast-type data having a virtual LAN MAC address mapped to the corresponding DCC channel, and transmits the data to the corresponding LAN subnetwork. When the data to be transmitted through one of the lower SDH systems is received through the LAN subnetwork, the data is converted into a point-to-point format and transmitted to a DCC channel corresponding to the corresponding virtual LAN MAC address. When the routing module receives the data of the broadcast format transmitted from the broadcast switching module on the LAN subnetwork and receives the data to be transmitted through one of the lower SDH systems, a corresponding DCC channel is received. Routing over a corresponding LAN subnetwork as a virtual LAN MAC address mapped to.