KR101010409B1 - Method and Apparatus for Transmitting IP Packet in Network Based on Tunneling - Google Patents

Abstract

An IP packet transmission method in a tunneling-based network according to an aspect of the present invention capable of splitting packets without degrading overall performance of the portable Internet system when transmitting packets between network devices included in the portable Internet system includes: The sum of the size of the IP packet and the size of the tunnel header received from the transmitting node is the maximum transmission unit (MTU) of the link between the first network device and the second network device. Dividing the IP packet into a plurality of IP packets when exceeding; In the first network equipment, performing tunneling by encapsulating each divided IP packet into the tunnel header, and then transmitting the received IP packet to a receiving node via a second network equipment; And recombining the split IP packets at the receiving node.

Tunnel, packet, split, MTU, GRE

Description

Method and Apparatus for Transmitting IP Packet in Tunneling Network [Method and Apparatus for Transmitting IP Packet in Network Based on Tunneling}

The present invention relates to packet transmission in communication networks, and more particularly, to packet transmission in tunneling based networks.

In a typical mobile Internet system configured as shown in FIG. 1, a Correspondent Node (CN) 110 communicating with a mobile station (MS) 100 is a home agent (HA) 120, a control station. (Access Router: ACR, 130) and the base station (Base Station: BS, 140) via the downlink packet to the terminal 100, the terminal 100 is the base station 140, the control station 130, and the home The uplink packet is transmitted to the counterpart node 110 via the agent 120.

In this portable Internet system, as shown in FIG. 2, communication is performed between the partner node 110 and the home agent 120 in the form of an IP packet, and IPinIP is performed between the home agent 120 and the control station 130. Communication is performed in the form of a packet using a tunnel, and communication is performed in the form of a packet using a Generic Routing Encapsulation (GRE) tunnel between the control station 130 and the base station 140.

As described above, in the case of a portable Internet system transmitting a packet based on a tunnel such as an IPinIP tunnel or a GRE tunnel, the size of a packet to be transmitted during a packet transmission process is the maximum transmission unit of a link between network devices. If the MTU is exceeded, the packet is fragmented and transmitted, and the divided packet is reassembled at the destination (terminal or counterpart) of the packet.

However, when a packet is transmitted based on a tunnel, the split packet in the middle of the tunnel passes through the tunnel and the end of the tunnel is not the final destination of the packet. Therefore, the split packet is not an intermediate network device such as a base station or a control station. Recombinant in

A general packet transmission method including the packet division and recombination described above will be described in detail with reference to FIG. 3. In FIG. 3, assuming that the maximum transmission unit of the link between each network equipment is 1500 bytes, assuming that the size of a packet transmitted from the counterpart node 110 to the control station 130 is 1500, the packet having a size of 1500 bytes is controlled. Since the station 130 needs to go through the GRE tunnel, as the total size of the packet increases by the size of the GRE header, the size of the entire packet becomes larger than the maximum transmission unit, and packet fragmentation is required. Specifically, assuming that the size of the GRE header is 28 bytes, the size of the tunneled packet is 1528 bytes, so the splitting of the packet is required at the control station 130, and the control station 130 stores the received packet, for example, 1478 bytes. The packet is divided into a packet of 28 bytes and a packet of 28 bytes in size.

In this case, since the divided two packets, that is, a packet having a size of 1478 bytes and a packet having a size of 28 bytes, are split with a GRE header attached, the base station 140 that is the end of the tunnel, not the terminal 100 that is the final destination of the packet, is divided. After recombination, tunnel termination must be performed. Such packet division may also occur in the case of an uplink packet transmitted from the terminal 100 to the counter node 110.

As such, when the packet is divided during the tunneling process, the control station 130 or the base station is performed by performing the recombination of the packet at the end of the tunnel that is not the final destination of the packet, such as the control station 130 or the base station 140. Buffering must occur until all packets divided for recombination of packets within a network device, such as 140, arrive. In this way, packets in a network device requiring real-time processing at wire speed are required. Storing it can cause a decrease in the overall performance of a portable Internet system.

In addition, packet recombination, which involves highly difficult and error-prone tasks such as queue management, buffering, and post-combination integrity check by IP header ID, is performed at the end of a tunnel such as a base station or a control station, rather than the final destination of the packet. Therefore, in the case of a portable Internet system using various kinds of tunnels, there is a problem in that the overall performance of the portable Internet system is degraded due to the repetition of splitting and recombination while the start and end of tunneling are repeated.

The present invention is to solve the above problems, to provide a method and apparatus for transmitting an IP packet in a tunneling-based network that can transmit packets without degrading the overall performance of the portable Internet system when transmitting packets between the network equipment included in the portable Internet system. Let it be technical problem.

In the tunneling-based network according to an aspect of the present invention for achieving the above object, the IP packet transmission method, in the first network equipment, the size of the IP (Internet Protocol) packet received from the transmitting node (Node) and the tunnel header ( Dividing the IP packet into a plurality of IP packets when a sum of sizes of headers exceeds a maximum transmission unit (MTU) of a link between the first network equipment and the second network equipment; In the first network equipment, performing tunneling by encapsulating each divided IP packet into the tunnel header, and then transmitting the received IP packet to a receiving node via a second network equipment; And recombining the split IP packets at the receiving node. Here, the tunnel may be a Generic Routing Encapsulation (GRE) tunnel.

In this case, when the IP packet is a downlink IP packet, the first network equipment is a control station and the second network equipment is a base station. When the IP packet is an uplink IP packet, the first network equipment is And the second network equipment is a control station.

In an embodiment, the splitting of the IP packet may include: splitting a payload of the IP packet into a plurality; And duplicating the IP header of the IP packet and combining the divided IP payloads.

Further, in the step of transmitting the divided IP packet, the divided IP packet is transmitted to the receiving node after the tunnel termination is performed by the second network equipment, wherein the tunnel termination processing is performed in the division. And a decapsulation process of removing an IP header and a GRE header from the received IP packet.

According to another aspect of the present invention, there is provided a method for transmitting an IP packet in a tunneling-based network, comprising: comparing a size of a received IP packet with a packet size that can be transmitted on a link between network equipment; And segmenting the payload of the IP packet when the IP packet is larger than the transmittable packet size, and then adding a tunnel header to transmit the packet, and when the IP packet is smaller than the transmittable packet size, And adding and adding a tunnel header, wherein the link between network devices transmits the IP packet using a GRE protocol.

An apparatus for transmitting an IP packet in a tunneling-based network according to another aspect of the present invention for achieving the above object is an apparatus for transmitting an IP packet in a portable Internet system including a first network equipment and a second network equipment. A packet dividing unit for dividing the IP packet into a plurality of IP packets when the sum of the size of the IP packet received from the transmitting node and the size of the tunnel header exceeds the maximum transmission unit of the link between network devices; A tunneling performing unit for performing tunneling by encapsulating each divided IP packet into the tunnel header; And a packet transceiver configured to receive the IP packet from the transmitting node and to transmit the tunneled fragmented IP packets to the receiving node via the second network equipment.

As described above, according to the present invention, when packet transmission is required for packet transmission between network devices included in the portable Internet system, the packet recombination, which involves complicated operations by dividing the packet before tunneling, is not the end of the tunnel. Since it is performed only at the final destination of the packet, it is possible to reduce the buffering time generated for recombination of the packet, thereby improving the overall performance of the system.

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

4 is a schematic structural diagram of a portable internet system including a packet transmission apparatus according to an embodiment of the present invention. As shown, the portable Internet system includes a terminal 430, a base station 440, a control station 410, a home agent 450, and the partner node 420, according to an embodiment of the present invention The transmission device 400 may be included in the control station 410 constituting the portable Internet system.

However, this is only an example of a downlink packet transmitted from a relative node (Correspondent Node: CN, 420) to the terminal 430, and is an uplink packet transmitted from the terminal 430 to the relative node 420 according to the present invention. The packet transmission apparatus 400 may be included in the base station 440. In another embodiment, the packet transmission apparatus 400 may be configured as a separate device from the control station 410 or the base station 440 and included in the portable Internet system.

Hereinafter, a case in which the packet transmission device 400 is included in the control station 410 and divides the downlink packet transmitted from the partner node 420 to the terminal 430 will be described as an example.

The packet transmission apparatus 400 includes a packet transceiver 402, a packet divider 404, and a tunneling performer 406 as shown.

The packet transceiver 402 receives the downlink packet received from the counterpart node 430 via the home agent 450 and transmits the tunneled divided packet transmitted from the tunneling performer 406 to be described later. Through the transmission to the terminal 430. In one embodiment, the packet transmitted from the partner node 430 via the home agent 450 may be an IP packet including an Internet Protocol (IP) header and an IP payload. In the following description, it is assumed that a packet transmitted from the counter node 430 is an IP packet for convenience of description.

When tunneling is required in the transmission of the IP packet received from the packet transceiver 402, the packet splitter 404 determines whether to split the received IP packet in consideration of the size of the received IP packet and the size of the tunnel header. If it is determined that segmentation of the IP packet is necessary, it divides the received IP packet. In one embodiment, the packet division unit 404 is the sum of the size of the received IP packet and the size of the tunnel header is the maximum transmission unit (MTU) of the link between the control station 410 and the base station 440 If exceeded, it is determined to split the received IP packet.

That is, the packet splitter 404 according to the present invention divides the IP packet after the tunnel header is combined when the size of the received IP packet exceeds the link maximum transmission unit between the control station 410 and the base station 440. Rather than splitting IP packets before the tunnel headers are combined, that is, before tunneling.

Here, tunneling is a data transmission method between networks using different protocols, and includes an encapsulation process, an encapsulation process, and an encapsulation process of attaching an additional header to the data for transmission of data to be transmitted. The logical path through which the encapsulated data passes through the process of decapsulation of the encapsulated data is called a tunnel.

Since data is transmitted between the control station 410 and the base station 440 by using a Generic Routing Encapsulation (GRE) tunnel, the packet splitter 404 according to the present invention receives an IP received through the packet transceiver 402. If the sum of the packet size and the size of the GRE tunnel header exceeds the maximum transmission unit of the link between the control station 410 and the base station 440, it is determined to split the packet.

When the packet dividing unit 404 determines to divide the received IP packet, a method of dividing the received IP packet will be described in detail with reference to FIG. 5. In FIG. 5, the packet splitter 404 divides one IP packet into three IP packets. As shown, the packet divider 404 divides the payload 510 included in the received IP packet 500 into a plurality of payloads 520a to 520c.

In addition, the packet splitter 404 duplicates the IP header 5120 included in the received IP packet 500, and then divides the duplicated IP headers 522a to 522c into the respective payloads 520a to 520c. ), One IP packet 500 is divided into a plurality of IP packets 530a to 530c.

In this case, in copying the IP header 512, the packet splitter 404 splits values of fields such as "TOTAL LENGTH", "FRAGMENT OFFSET", and "HEADER CHECKSUM" included in the IP header 512. The modified IP packets 530a to 530c are modified.

Referring back to FIG. 4, the tunneling performer 406 recognizes the IP packets divided by the packet divider 404 as independent packets, and performs tunneling on each of the divided IP packets. That is, the tunneling performer 404 tunnels the divided IP packets by combining the GRE headers with each of the divided IP packets to encapsulate each of the divided IP packets.

The divided IP packets tunneled by the tunneling performer 406 are delivered to the base station 440 through the above-described packet transceiver 404, and the base station 440 is configured with an IP header and a GRE header from the tunneled divided IP packets. After tunnel termination processing is performed by eliminating (i.e., decapsulating the tunneled fragmented IP packets), the fragmented IP packet is transmitted to the terminal 430 which is the final destination of the IP packet. Thereafter, the terminal 430 reassembles the divided IP packet by using information included in the IP header of the divided IP packet.

As described above, in the present invention, the IP packet transmitted from the counterpart node is not split in the middle of tunneling, but the packet splitter 404 splits the received IP packet before tunneling, and the split IP packets are independently tunneled. Tunneled by 406, the IP packet transmitted from the counterpart node is recombined at the terminal 430 as the end destination of the packet, not at the base station 440 as the end of the tunnel.

An example in which the packet transmission apparatus 400 according to an embodiment of the present invention divides an IP packet received from a counterpart node will be described with reference to FIG. 6. In FIG. 6, it is assumed that the size of the IP packet received from the counterpart node 420 is 1500 bytes, the maximum link transmission unit between the control station 410 and the base station 440 is 1500 bytes, and the size of the GRE header is 28 bytes. .

Since the packet transmission apparatus 400 included in the control station 410 has a size of 1500 bytes of received IP packets and a size of 28 bytes of a GRE header, the sum thereof is between the control station 410 and the base station 440. Since the link maximum transmission unit is exceeded, it is decided to divide the received IP packet. In the example illustrated in FIG. 6, the packet transmission apparatus 400 may divide the received IP packet into, for example, a packet having a size of 1400 bytes and a packet having a size of 100 bytes. However, the number of divided packets and the size of the divided packets may be variously changed.

Subsequently, the packet transmission apparatus 400 independently tunnels the divided IP packets by combining the GRE headers for each of the divided IP packets to encapsulate each of the divided IP packets, and then transmits the tunneled divided IP packets to the base station 440. ). Meanwhile, since the base station 440 does not split the tunneled segmented IP packet transmitted from the control station 410 during the tunneling process, the base station 440 performs only tunnel termination without recombining the tunneled segmented IP packet, that is, After performing the decapsulation process of removing the IP header and the GRE header from the tunneled fragmented IP packet, the fragmented IP packet is transmitted to the terminal 430 which is the final destination of the IP packet. Afterwards, the terminal 430 receiving the split IP packet reassembles the split IP packet.

In the above-described embodiment, the packet transmission apparatus 400 has been described as being included in the control station 410, but as described above, this is only an example of the case of the downlink packet transmitted from the counterpart node 420 to the terminal 430. In the case of an uplink packet transmitted from 430 to the counter node 420, the packet transmission apparatus 400 may be included in the base station 450. In this case, the uplink packet is split by the base station 440 and recombined at the counter node 420.

Hereinafter, a packet transmission method according to an embodiment of the present invention will be described with reference to FIG. 7. 7 is a flowchart illustrating a method of transmitting a downlink IP packet according to an embodiment of the present invention. As shown, when the partner node 420 transmits the IP packet via the home agent (S700), the packet transmission apparatus 400 included in the control station 410 receives the IP packet (S705). Thereafter, the packet transmission apparatus 400 determines whether the sum of the size of the received IP packet and the size of the tunnel header exceeds the maximum transmission unit of the link between the control station and the base station (S710). In one embodiment, the tunnel may be a GRE tunnel and the tunnel header may be a GRE header.

As a result of determination, when the sum of the size of the received IP packet and the size of the tunnel header exceeds the maximum transmission unit, the packet transmission apparatus 400 divides the received IP packet into a plurality of IP packets (S720). In one embodiment, the segmentation of the received IP packet is divided into a plurality of payloads included in the received IP packet, a duplicate of the IP header included in the received IP packet, and then a plurality of divided IP headers It is performed by combining with payloads respectively.

Next, the packet transmission apparatus 400 independently tunnels the divided IP packets by combining the GRE headers with each of the divided IP packets to encapsulate the divided IP packets (S725), and transmits them to the base station 440. (S730).

Thereafter, the base station 440 performs tunnel termination through a decapsulation process of removing the IP header and the GRE header from the tunneled split IP packet (S740), and then transmits the split IP packet to the terminal 430. (S750).

Finally, the terminal 430 reassembles the divided IP packets using the information included in the IP headers of the divided IP packets transmitted from the base station 440 (S760). As such, when the segmentation of the received IP packet is required during the tunneling process, the present invention does not segment the corresponding IP packet during the tunneling process, but divides the segmented IP packet before the tunneling process. Allow recombination at the packet's final destination.

On the other hand, if the sum of the size of the IP packet and the size of the tunnel header received in the S710 does not exceed the maximum transmission unit, since splitting of the IP packet is not necessary, the IP packet is encapsulated in a GRE header according to a general procedure. After the tunneling is provided (S770) to the base station 440 (S780), the base station 440 is provided to the terminal 430 after the tunnel termination processing (S790) by decapsulating the received IP packet (S800). ).

In the above-described embodiment, a method of transmitting a downlink IP packet has been described. However, in the case of the uplink IP packet, the packet transmission apparatus 400 included in the base station 440 is transmitted from the terminal 430 to the counter node 420. The only difference is that the uplink IP packet is split, the control station 410 performs tunnel termination processing of the tunneled fragmented IP packets, and the counterpart node 420 reassembles the fragmented IP packets. Since the process is the same as that of the packet transmission, a detailed description thereof will be omitted.

The above-described packet transmission method may be implemented in the form of program instructions that can be executed by various computer means and recorded in a computer-readable recording medium. In this case, the computer-readable recording medium may include program instructions, data files, data structures, and the like, alone or in combination. On the other hand, the program instructions recorded on the recording medium may be those specially designed and configured for the present invention or may be available to those skilled in the art of computer software.

The computer-readable recording medium includes a magnetic recording medium such as a magnetic medium such as a hard disk, a floppy disk and a magnetic tape, an optical medium such as a CD-ROM and a DVD, a magnetic disk such as a floppy disk, A magneto-optical media, and a hardware device specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. The recording medium may be a transmission medium such as an optical or metal wire, a waveguide, or the like including a carrier wave for transmitting a signal specifying a program command, a data structure, or the like.

In addition, program instructions include not only machine code generated by a compiler, but also high-level language code that can be executed by a computer using an interpreter or the like. The hardware device described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

On the other hand, those skilled in the art will understand that the present invention described above can be implemented in other specific forms without changing the technical spirit or essential features.

Therefore, it is to be understood that the embodiments described above are exemplary in all respects and not restrictive. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention. do.

1 is a diagram showing the configuration of a typical mobile Internet system.

2 is a view showing the form of a packet used in a typical mobile Internet system.

3 shows an example of a packet transmission method according to the prior art.

4 is a block diagram of a portable Internet system including a packet transmission apparatus according to an embodiment of the present invention.

5 is a diagram schematically illustrating a packet division method.

6 shows an example of a packet transmission method according to the present invention.

7 is a flowchart showing a packet transmission method according to an embodiment of the present invention.

Claims (17)

In the first network equipment, the sum of the size of the IP (Internet Protocol) packet received from the transmitting node and the size of the tunnel header is the maximum transmission unit of the link between the first network equipment and the second network equipment ( Dividing the IP packet into a plurality of IP packets when the Maximum Transmission Unit (MTU) is exceeded; In the first network equipment, performing tunneling by encapsulating each divided IP packet into the tunnel header, and then transmitting the received IP packet to a receiving node via a second network equipment; And Recombining the split IP packets at the receiving node; In the step of transmitting the divided IP packet, the divided IP packet is transmitted to the receiving node after the tunnel termination process by the second network equipment, IP packet transmission method in a tunneling-based network. In the first network equipment, the sum of the size of the IP (Internet Protocol) packet received from the transmitting node and the size of the tunnel header is the maximum transmission unit of the link between the first network equipment and the second network equipment ( Dividing the IP packet into a plurality of IP packets when the Maximum Transmission Unit (MTU) is exceeded; In the first network equipment, performing tunneling by encapsulating each divided IP packet into the tunnel header, and then transmitting the received IP packet to a receiving node via a second network equipment; And Recombining the split IP packets at the receiving node; If the IP packet is a downlink IP packet, the first network equipment is a control station and the second network equipment is a base station, and if the IP packet is an uplink IP packet, the first network equipment is a base station and the second network. Equipment is a control station IP packet transmission method in a tunneling-based network, characterized in that. In the first network equipment, the sum of the size of the IP (Internet Protocol) packet received from the transmitting node and the size of the tunnel header is the maximum transmission unit of the link between the first network equipment and the second network equipment ( Dividing the IP packet into a plurality of IP packets when the Maximum Transmission Unit (MTU) is exceeded; In the first network equipment, performing tunneling by encapsulating each divided IP packet into the tunnel header, and then transmitting the received IP packet to a receiving node via a second network equipment; And Recombining the split IP packets at the receiving node; The tunnel is a method of transmitting an IP packet in a tunneling-based network, characterized in that the GRE (Generic Routing Encapsulation) tunnel. The method of claim 1, 2 or 3, wherein the IP packet segmentation step, Dividing a payload of the IP packet into a plurality; And And duplicating the IP header of the IP packet and combining the divided IP payloads with each of the divided payloads. delete delete The method of claim 1, The tunnel termination process is performed through a decapsulation process of removing an IP header and a GRE header from the split IP packet. Comparing the size of the received IP packet with the packet size transmittable on a link between network equipment; And If the IP packet is larger than the transmittable packet size, the payload of the IP packet is divided, and then a tunnel header is added and transmitted. If the IP packet is smaller than the transmittable packet size, the tunnel is added to the IP packet. Adding the header and transmitting the header; The link between the network equipment transmits the IP packet using a GRE protocol, And when the payload of the IP packet is divided, the divided payloads of the IP packet are reassembled at the final receiving end of the IP packet. The method of claim 8, wherein the division of the payload of the IP packet is performed by dividing the payload of the IP packet into a plurality of copies, and copying the IP header of the IP packet to combine the divided payloads. IP packet transmission method in a tunneling-based network. delete An apparatus for transmitting an IP packet in a portable internet system including a first network equipment and a second network equipment, A packet dividing unit for dividing the IP packet into a plurality of IP packets when the sum of the size of the IP packet received from the transmitting node and the size of the tunnel header exceeds the maximum transmission unit of the link between network devices; A tunneling performing unit for performing tunneling by encapsulating each divided IP packet into the tunnel header; And A packet transceiver configured to receive the IP packet from the transmitting node, and transmit the tunneled divided IP packets to a receiving node via the second network equipment; The tunnel is an IP packet transmission device in a tunneling-based network, characterized in that the GRE tunnel. An apparatus for transmitting an IP packet in a portable internet system including a first network equipment and a second network equipment, A packet dividing unit for dividing the IP packet into a plurality of IP packets when the sum of the size of the IP packet received from the transmitting node and the size of the tunnel header exceeds the maximum transmission unit of the link between network devices; A tunneling performing unit for performing tunneling by encapsulating each divided IP packet into the tunnel header; And A packet transceiver configured to receive the IP packet from the transmitting node, and transmit the tunneled divided IP packets to a receiving node via the second network equipment; The tunneled segmented IP packets transmitted via the second network equipment are tunnel terminated by the receiving node and then recombined in the tunneling-based network. The method of claim 12, Tunnel termination processing of the tunneled fragmented IP packets is performed by a decapsulation process of removing an IP header and a GRE header from the tunneled fragmented IP packets. . An apparatus for transmitting an IP packet in a portable internet system including a first network equipment and a second network equipment, A packet dividing unit for dividing the IP packet into a plurality of IP packets when the sum of the size of the IP packet received from the transmitting node and the size of the tunnel header exceeds the maximum transmission unit of the link between network devices; A tunneling performing unit for performing tunneling by encapsulating each divided IP packet into the tunnel header; And A packet transceiver configured to receive the IP packet from the transmitting node, and transmit the tunneled divided IP packets to a receiving node via the second network equipment; When the IP packet is a downlink IP packet, the first network equipment is a control station and the second network equipment is a base station. When the IP packet is an uplink IP packet, the first network equipment is a base station and the second network equipment is IP packet transmission apparatus in a tunneling-based network, characterized in that the control station. The method according to any one of claims 11, 12, or 14, The packet transmission apparatus is included in the first network equipment and the second network equipment IP packet transmission apparatus in a tunneling-based network, characterized in that. The method according to any one of claims 11, 12, or 14, The packet dividing unit divides the IP packet by dividing the payload of the IP packet into a plurality, and then copies the header of the IP packet and combines the divided payloads with each of the divided payloads. Packet transmission device. delete

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