KR100445665B1 - Communication network management device and method for distributing datas in various bandwidth - Google Patents

Abstract

The present invention relates to a communication network management apparatus and method for distributing a plurality of bandwidth data, the communication network management apparatus of the present invention is a local network, a router device for routing the packet data generated in the local network to the external network and A packet which is connected to a second data transmission path for transmitting data having a different bandwidth from the first data transmission path connected to the router device, intercepts packet data transmitted from the local network to the router device, and analyzes header information of the packet data. An analysis unit, a distributed processor for bypassing the packet data transmitted through the first data transmission path, and changing the header information of the packet data transmitted through the second data transmission path; The packet data is transmitted to the router apparatus to transmit packet data to the first data transmission path. And a second interface unit connected to the second data transmission path and transmitting packet data whose header information is changed in the distribution processor to the second data transmission path. Therefore, the present invention is characterized in that the distributed processing can be implemented by changing only the header information of the packet data passing through the communication network management apparatus of the present invention, rather than acting as a gateway.

Description

Communication network management device and method for distributing a plurality of bandwidth data and a method therefor {Communication network management device and method for distributing datas in various bandwidth}

The present invention relates to a network management apparatus and a method thereof, and in particular, connected to a plurality of data transmission paths for transmitting data having different bandwidths, and the plurality of data according to a filtering result for packet data transmitted from a local network. The present invention relates to a communication network management apparatus and method for selecting one of the data transmission paths and transmitting the packet data.

Recently, with the popularization of the Internet, various and convenient Internet applications have become popular, and the traffic on the Internet is rapidly increasing, and the traffic congestion has seriously slowed down the speed of the network. The easiest way to address this congested traffic problem is to upgrade Wide Area Network (WAN) circuits. However, the circuit upgrade is a temporary solution, and there is a problem in that when the circuit is upgraded every time a traffic problem occurs, a high circuit cost is continuously generated and a shortage of bandwidth due to the rapidly increasing traffic is not encountered.

Therefore, in the related art, a plurality of data transmission paths supporting different bandwidth services are connected to a router in charge of routing packet data transmitted from the inside of the local network to the outside, and the packet data in the router is set by a predetermined filtering condition. After the filtering result is applied, one method of selecting one data transmission path among the plurality of data transmission paths is used, and a method of transmitting packet data using the data transmission path is mainly used.

1 is an exemplary view of such a conventional method. Referring to FIG. 1, in the related art, the router 20 connected to the local network 10 is configured to simultaneously perform the functions of a gateway and a backup device. This is to allow the router 20 to interwork with a plurality of data transmission paths 30 and 40 supporting different bandwidth services. In the example of FIG. 1, these data transmission paths 30 and 40 are represented by the main line 30 and the auxiliary line 40. In this case, the terminals included in the local network 10 should designate the router 20 as a gateway.

After configuring the network as described above, if any terminal 11 in the local network 10 configures and transmits packet data to transmit data to the external network, the router 20 determines the transmission path of the packet data. To do the filtering. That is, the router 20 performs filtering according to a preset filtering condition in order to determine whether to transmit the packet data to the main line 30 or the auxiliary line 40. At this time, the filtering conditions are set when the network is configured, and can be changed at any time by the network administrator. The filtering condition uses the information recorded in the header portion of the packet data, and mainly uses the destination IP address of the packet data.

For example, when the filtering condition of the packet data to be transmitted to the main line 30 is set to 'destination IP address → 192.9.xxx.xxx', the router 20 may determine that the destination IP address among the received packet data is' 192.9. Only packet data of .xxx.xxx 'is transmitted to the main line 30, and others are transmitted to the auxiliary line 40.

However, in order to distribute the plurality of bandwidth data by using the method illustrated in FIG. 1, it is necessary to replace all existing routers that perform only the gateway function with routers that simultaneously perform the functions of the gateway function and the backup device. have. In addition, when the router 20 itself is defective, terminals in the local network 10 having the router 20 as a gateway have a disadvantage in that data transmission / reception with the external network is blocked.

In order to make up for this disadvantage, conventionally, as illustrated in FIG. 1A, an additional backup device 15 is additionally installed so that the backup device 15 plays a role of a gateway in the direction of the auxiliary line 40a. To this end, terminals included in the local network 10a should designate the backup device 15 as a gateway.

Then, when any terminal 11a in the local network 10a configures and transmits packet data to transmit data to the external network, the backup device 15 filters the packet data to the main line 30a through filtering. It is determined whether to be transmitted to the auxiliary line 40a. As a result, the packet data to be transmitted to the auxiliary line 40a is distributed to the auxiliary line 40a, and the packet data to be transmitted to the main line 30a is transmitted to the main line 30a through the router 20a. To the router 20a. At this time, the filtering process of the backup device 15 is omitted because it is similar to the content mentioned in the description with reference to FIG.

As described above, in order to implement the contents illustrated in FIG. 1A, it is not necessary to replace all the existing routers as illustrated in FIG. 1, but the gateway information of all the terminals included in the local network 10a may be backed up. Should be corrected). In addition, when the backup device 15 itself is defective, gateway information of all terminals included in the local network 11a should be changed to the router 20a.

That is, in the case of distributing a plurality of bandwidth data by using the method illustrated in FIG. 1A, only the gateway information of each terminal included in the local network 11a is changed without replacing hardware itself. It is a feature that a plurality of bandwidth data can be distributed in a more convenient way than the conventional method.

However, the method illustrated in FIG. 1A also has a disadvantage in that the gateway information of all the terminals included in the local network 10a must be changed every time the backup device 15 is added, deleted, or changed.

SUMMARY OF THE INVENTION The present invention has been made to solve this disadvantage, and an object of the present invention is to distribute a plurality of bandwidth data without replacing a gateway constituting an existing network or changing gateway information of terminals included in a local network. The present invention provides a communication network management apparatus and a method thereof.

1 and 1A illustrate an example of a network configuration for distributing a plurality of bandwidth data in a conventional manner.

2 is an exemplary network configuration for distributing a plurality of bandwidth data according to an embodiment of the present invention;

3 is a functional block diagram of a communication network management apparatus for distributing a plurality of bandwidth data according to an embodiment of the present invention;

4 is a flowchart illustrating a communication network management method for distributing a plurality of bandwidth data according to an embodiment of the present invention.

♣ Explanation of symbols for the main parts of the drawing ♣

200: communication network management device 210: packet analysis unit

220: distributed processing unit 230: first interface unit

240: second interface unit

In order to achieve the above object, a communication network management apparatus provided by the present invention is different from a local network, a router device for routing packet data generated in the local network to an external network, and a first data transmission path connected to the router device. A packet analysis unit connected to a second data transmission path for transmitting data of bandwidth and intercepting packet data transmitted from a local network to a router device, and analyzing header information of the packet data, and the first data transmission path as a result of the analysis; The packet data transmitted to the second data transmission path is bypassed, and the packet data transmitted to the second data transmission path includes a distributed processor that changes its header information, and transmits the packet data bypassed by the distributed processor to the first data transmission path. A first interface unit for transmitting the packet data to the router device, and the second data transmission unit It is connected to the path, characterized in that it comprises a second interface unit for transmitting the packet data whose header information is changed in the distribution processor to the second data transmission path.

In addition, the communication network management method provided by the present invention to achieve the above object is a local network, a router device for routing the packet data generated in the local network to the external network and a first data transmission path connected to the router device; A communication network management method of a communication network management device connected to a second data transmission path for transmitting data having different bandwidths, the method comprising: intercepting packet data transmitted from a local network to a router device and analyzing header information of the packet data; And a second process of bypassing the packet data transmitted in the first data transmission path to the router device as a result of the analysis of the first process, and changing the header information of the packet data transmitted in the second data transmission path; And a third process of transmitting the packet data whose header information is changed in the second process to the second data transmission path. It is characterized by.

Hereinafter, a preferred embodiment of a network management apparatus and a method provided by the present invention will be described in detail with reference to the accompanying drawings.

2 is a diagram illustrating a network configuration for distributing a plurality of bandwidth data according to an embodiment of the present invention. Referring to FIG. 2, in order to distribute the plurality of bandwidth data according to an embodiment of the present invention, the communication network management apparatus 200 of the present invention may include a local network 100, a router 300, and an auxiliary line 500. It is characterized in that the connection.

At this time, the router 300 is connected to the main line 400 is a device for routing the packet data generated in the local network 100 to the external network, the auxiliary line 500 is different from the main line 400 The data transmission path for transmitting data of bandwidth. That is, the main line 400 and the auxiliary line 500 refer to data transmission paths supporting different bandwidth services. In FIG. 2, the main line 400 and the auxiliary line 500 are divided into the main line 400 and the auxiliary line 500 for convenience.

In this case, the terminals included in the local network 100 designate the router 300 as a gateway. This is because, in the drawings, the terminals in the local network 100 are transmitted to the router 300 through the communication network management apparatus 200, but the communication network management apparatus 200 does not operate as a gateway. That is, the communication network management apparatus 200 analyzes the header information of the packet data passing through the communication network management apparatus 200 to identify only the packet data to be transmitted to the auxiliary line 500, and changes the header information of the packet data. Do this. As a result, the packet data is distributed to the auxiliary line 500. This series of processes will be described in more detail in the description with reference to FIG. 3. Meanwhile, as a result of analyzing the header information of the packet data, the packet data to be transmitted to the main line 400 is bypassed to the router 300 without being received by the communication network management apparatus 200.

Accordingly, the communication network management apparatus 200 may distribute the plurality of bandwidth data without affecting the network setting information of the preset local network 100 at all.

In addition, when a fault occurs in the communication network management apparatus 200, all packet data passing through the communication network management apparatus 200 is automatically transmitted to the router 300 which is the gateway of the local network 100. The same is done even in a situation where no power is supplied. Therefore, the network to which the communication network management apparatus 200 is connected can ensure the provision of a stable communication service.

An embodiment of such a network management apparatus 200 is shown in FIG. 3. 3 is a functional block diagram of a communication network management apparatus 200 for distributing a plurality of bandwidth data according to an embodiment of the present invention. Referring to FIG. 3, the network management apparatus according to an exemplary embodiment of the present invention includes a packet analyzer 210, a distributed processor 220, a first interface 230, and a second interface 240.

2 and 3, the operation of the network management apparatus 200 of the present invention in more detail as follows.

The packet analyzer 210 intercepts packet data transmitted from the local network 100 to the router and analyzes header information of the packet data. In particular, among the information included in the header information of the packet data, the destination information (eg, the destination IP address, the destination MAC address, etc.) is analyzed. Then, based on the analysis result and the predetermined filtering reference information, information about a transmission path to which the corresponding packet data is transmitted is obtained.

In this case, filtering is a series of processes for providing different bandwidth services based on a predetermined criterion, and a detailed processing method thereof is omitted in the present specification because it is already known as mentioned in the description with reference to FIG. 1. do. In addition, the reference information for filtering may use a variety of information included in the header information of the packet data, in particular, the address information (eg, the IP address of the destination, the MAC address of the destination) of the destination included in the header information of the packet data. Etc.) is generally used as filtering criteria information.

The distribution processor 220 bypasses the packet data transmitted to the main line 400 as a result of the analysis of the packet analyzer 210, and changes the header information of the packet data transmitted to the auxiliary line 500. That is, the packet analysis unit 210 receives the information on the transmission path to which the packet data is to be transmitted, and based on the information to transmit the packet data to the main line 400 to be transmitted to the auxiliary line 500. After determining whether the packet data transmitted to the main line 400 is bypassed, the packet data transmitted to the auxiliary line 500 transfers the destination information of the packet data to MAC of the communication network management apparatus 200. Access Control) address. This is because the communication network management apparatus 200 operates as a gateway for packet data going to the auxiliary line 500. At this time, since the MAC address is known to those skilled in the art, a detailed description of the MAC address is omitted. On the other hand, using the MAC address other than the IP address of the network management apparatus 200 as the address information of the network management apparatus 200 is the destination of the packet data when the packet data is transferred in the local network. This is because the primary reference to determine the destination MAC address.

In addition, the first interface unit 230 transmits the packet data bypassed by the distributed processor 220 to the main line 400, and transmits the packet data to the router 300 connected to the main line 400, and the auxiliary line ( The second interface unit 240 connected to the 500 transmits the packet data whose header information is changed by the distributed processor 220 to the auxiliary line 500.

4 is a flowchart illustrating a communication network management method for distributing a plurality of bandwidth data according to an embodiment of the present invention. Referring to FIG. 4, as shown in FIG. 2, a communication network management method of a communication network management apparatus connected to a local network, a router, and an auxiliary line is as follows.

First, when packet data transmitted from the local network to the external network occurs, the communication network management device intercepts the packet data and analyzes the header information of the packet data (S110). That is, after analyzing the header information of the packet data, based on the predetermined filtering criteria information and the analysis result, the information on the transmission path to which the packet data is to be transmitted is obtained. In this case, since the description of 'filtering' and 'filtering reference information' are mentioned in the description with reference to FIG. 3, the description thereof will be omitted. In addition, a technique for intercepting packet data is applied to a highly developed hacking technology with the development of communication technology, and thus a detailed description thereof will be omitted since it is obvious to those skilled in the art.

When the header information of the packet data is analyzed as described above, the next routing path is determined based on the analysis result (S120). That is, it is determined whether the packet data is to be transmitted to the primary line or the secondary line. In this case, the main line and the auxiliary line refers to a data transmission path for transmitting data having different bandwidths, and are divided into main lines and auxiliary lines for convenience.

In addition, the determination of the next routing path in the process (S120) is based on the information on the transmission path of the packet data obtained through the process (S110). As a result of the determination (S120), the next routing path is the 'secondary line. ', The header information of the packet data-more specifically, the destination address information-is changed (S130). That is, the destination address information of the packet data is changed to the MAC address of the device acting as a gateway of the 'secondary line' (in the example of FIG. 3, the communication network management device 200). Then, the packet data is transferred to the auxiliary line (S140). Meanwhile, as a result of the determination (S120), when the next routing path is the 'main line', the packet data is bypassed to the router (S150).

The above description is merely an example of an embodiment, and the present invention is not limited to the above-described embodiment and can be variously changed within the scope of the appended claims. For example, the shape and structure of each component specifically shown in the embodiment of the present invention can be modified.

The network management apparatus and method provided by the present invention are characterized by being capable of implementing distributed processing by changing only header information of packet data passing through the communication network management apparatus of the present invention, rather than operating as a gateway. As a result, a plurality of bandwidth data may be distributed without replacing a gateway constituting an existing network or changing gateway information of terminals included in a local network.

In addition, when a communication network management apparatus of the present invention is defective, it is possible to prevent the loss of the network due to the defect of the device by bypassing the packet data transmitted from the local network to the preset gateway. This operation is similarly performed even in a situation where no power is supplied. Therefore, the network management apparatus and method of the present invention has the effect that it is possible to ensure the stability of the network even if any error occurs.

Claims (6)

A local network, a router device for routing packet data generated in the local network to an external network, and a second data transmission path for transmitting data having a different bandwidth from the first data transmission path connected to the router device, A packet analyzer which intercepts packet data transmitted from the local network to the router device and analyzes header information of the packet data; A distributed processor for bypassing packet data transmitted in the first data transmission path and changing the header information of the packet data transmitted in the second data transmission path; A first interface unit for transmitting the packet data to the router device to transmit the packet data bypassed by the distribution processor to the first data transmission path; And a second interface unit connected to the second data transmission path and transferring the packet data whose header information is changed in the distribution processor to the second data transmission path. The method of claim 1, wherein the packet analysis unit And analyzing the header information of the packet data and obtaining destination information of the packet data based on preset filtering criteria information and the analysis result. According to claim 1 or claim 2, wherein the dispersion processing unit The packet data to be transmitted in the second data transmission path is determined based on the destination information of the packet data obtained by the packet analyzer, and the destination information of the packet data to be transmitted in the second data transmission path is determined by the MAC of the network management apparatus. Communication network management apparatus, characterized in that for changing to an address. Local area network, a router device for routing packet data generated in the local network to an external network, and a communication network management device connected to a second data transmission path for transmitting data having a different bandwidth from the first data transmission path connected to the router device In the network management method of, A first step of intercepting packet data transmitted from the local network to the router device and analyzing header information of the packet data; A second process of bypassing the packet data transmitted in the first data transmission path to the router device as a result of the analysis of the first process, and changing the header information of the packet data transmitted in the second data transmission path; And a third process of transmitting the packet data whose header information is changed in the second process to the second data transmission path. The method of claim 4, wherein the first process is And analyzing header information of the packet data and obtaining destination information of the packet data based on preset filtering criteria information and the analysis result. The method of claim 4 or 5, wherein the second process The packet data to be transmitted in the second data transmission path is determined based on the destination information of the packet data obtained in the first step, and the destination information of the packet data to be transmitted in the second data transmission path is determined by the MAC of the network management apparatus. Communication network management method, characterized in that for changing to an address.