KR102109840B1 - HIP network communication method and system - Google Patents

Abstract

In a communication method of a HIP network, a mobile router in a mobile network receives a control message to be transmitted from a terminal to a Host Identity Protocol (HIP) Rendezvous Server (RVS). The mobile router stores the HIT (Host Identity Tag) of the terminal and the IP address of the terminal from the control message. By changing the IP address of the stored terminal to the Care-of-Address (CoA) of the mobile router, the control message is updated, and the updated control message is transmitted to the HIP RVS.

Description

HIP network communication method and system

This disclosure relates to a method and system for communication in a HIP network.

Host Identity Protocol (HIP) was registered as an experimental document in 2008 by the Internet Engineering Task Force (IETF) and version 2.0 was registered as a standard in 2015. The key idea of HIP is to overcome the limitations of mobility and multi-homing support caused by the existing IP simultaneously performing the functions of identifier and locator, while ensuring a secure connection.

The HIP is designed in consideration of only the movement of the terminal unit. When the movement of the network unit occurs, the problem of a large increase in the amount of control messages for notifying the location information change occurs. In addition, in a network to which the Network Mobility Basic Support (hereinafter referred to as NEMO-BS) defined by the IETF is applied, the advantage of HIP is that even if the network access point is changed, the location change is not recognized and the location and identifier are separated and the location reflects the latest location. Will not be saved. Accordingly, HIP-NEMO, NeMHIP, and the like have been proposed to add the mobility support function of the network unit to the HIP itself.

However, both HIP-NEMO and NeMHIP have not been applied to the Internet because they are not considering interworking with standards that are separately promoted to support mobility of terminals and network mobility.

The present invention proposes a HIP-based mobility support method that can be applied to a real Internet environment in conjunction with NEMO-BS and Distributed Mobility Management (hereinafter DMM), which are mobility support standards developed around IETF.

It is to provide a communication method and system of the HIP network.

The technical problems to be achieved by the present embodiment are not limited to the technical problems as described above, and other technical problems may be inferred from the following embodiments.

As a means for solving the above-described technical problem, according to an aspect, a communication method of a HIP network receives a control message to be transmitted to a Host Identity Protocol (HIP) RVS (Rendezvous Server) from a mobile station in a mobile network by a mobile router in a mobile network. To do; Storing a host identity tag (HIT) of the terminal and an IP address of the terminal from the control message; Updating the control message by changing the IP address of the stored terminal to a Care-of-Address (CoA) of the mobile router; And transmitting the updated control message to the HIP RVS.

According to some embodiments, the step of transmitting the updated control message to the HIP RVS comprises: when the mobile network belongs to the upper mobile network, the mobile router transmitting the updated control message to the upper mobile router of the upper mobile network; Storing, by the upper mobile router, the HIT of the terminal and the IP address of the mobile router from the updated control message; Updating the control message by changing the IP address of the mobile router where the upper mobile router is stored to a Care-of-Address (CoA) of the upper mobile router; And transmitting, by the upper mobile router, the re-updated control message to the HIP RVS.

According to another aspect, the HIP network system includes: a Host Identity Protocol (HIP) Rendezvous Server (RVS); Terminal; And mobile routers; Including, the mobile router receives a control message to be transmitted to the HIP RVS from the terminal, stores the HIT (Host Identity Tag) of the terminal and the IP address of the terminal from the control message, and stores the IP address of the stored terminal of the mobile router. By changing to Care-of-Address (CoA), the control message is updated, and the updated control message is transmitted to the HIP RVS.

1 is a diagram illustrating an example of a HIP network system.
2 is a diagram illustrating an example of an HIP overlapping mobile network environment.
3 is a diagram illustrating an example of a registration process of a terminal in a HIP overlapping mobile network to HIP RVS.
4 is a diagram illustrating an example of a connection establishment process between a terminal and a node.
5 is a diagram illustrating an example of location update when the address of the mobile network is changed.
6 is a diagram illustrating an example of a location update and a data transmission path when an address of a terminal in a mobile network is changed.
7 is a flowchart illustrating an example of a process of registering a terminal in a HIP network with HIP RVS.

The terminology used in the present embodiments was selected from general terms that are currently widely used as possible while considering functions in the present embodiments, but this may vary depending on the intention or precedent of a person skilled in the art or the appearance of new technology. Can be. In addition, in certain cases, some terms are arbitrarily selected, and in this case, their meanings will be described in detail in the description of the corresponding embodiment. Therefore, the terms used in the present embodiments should be defined based on the meaning of the terms and the contents of the present embodiments, not simply the names of the terms.

In the descriptions of the embodiments, when a part is connected to another part, this includes not only the case of being directly connected, but also the case of being electrically connected with another component in between. . Also, when a part includes a certain component, this means that other components may be further included rather than excluding other components unless otherwise specified.

The terms "consisting of" or "comprising" as used in the embodiments should not be construed to include all of the various components, or various steps described in the specification, and some of them, or It should be construed that some steps may not be included, or may further include additional components or steps.

The description of the following embodiments should not be construed as limiting the scope of rights, and those that can be easily inferred by those skilled in the art should be interpreted as belonging to the scope of rights of the embodiments. Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings.

1 is a diagram illustrating an example of a HIP network system.

Referring to FIG. 1, the HIP network system 10 considered in the present invention includes a mobile terminal 100 (Mobile Node, MN), a mobile router 110 (Mobile Router, MR) and a Rendezvous Server 120 ( Hereinafter, RVS) is included.

The MN 100 is a device that accesses a network using wireless communication technology such as WiFi.

The MN 100 handles the process of registering its identifier and current location (ie, IP address) to the RVS. MN 100 transmits a HIP control message to RVS 120 for registration.

The MR 110 is a mobile device with a routing function. The MR 110 is treated as a terminal to a router of an upper mobile network of a mobile network constituted by the MR 110, and is recognized as a router to a terminal utilizing the routing function of the device. The mobile terminals that recognize the MR 110 and the MR 110 as routers form one independent network, and the network configured by the MR 110 is called a mobile network.

The MR 110 of the mobile network to which the MN 100 belongs is located on the paths of the MN 100 and the RVS, so that a HIP control message can be received and the MR 110 of the mobile network configured by the MR 110. Acquire identifier information. Since the HIP control message is implemented as an extension header of IPv6, it is possible for the MR 110 located on the path of the MN 100 and RVS 120 to receive the HIP control message.

The MR 110 receives a control message to be transmitted to the RVS 120 from the MN 100, and a host identity tag (HIT) and IP address of the MN 100 from the control message are called a SNI (Serving Node Information) database. To save. Thereafter, the sender address of the control message is changed from an IP address of the MN 100 to a care-of-address (CoA) of the MR 110 and transmitted to the RVS. Through this process, the HV of the MN 100 and the IP address of the MR 110 may be stored in the RVS 120 as registration information of the MN 100.

RVS 120 is a device that implements Rendezvous service. Terminals that understand HIP can know the address of RVS 120 by Domain Name Service or HIP system configuration information.

The RVS receiving the control message from the MN 100 stores the IP address of the sender of the control message in the SNI as a location corresponding to the HIT of the MN 100. Subsequently, when control message I1 requesting connection establishment to MN 100 is received, I1 is delivered to the IP address registered in SNI.

In FIG. 1, only the MN 100 is illustrated as a mobile terminal in a mobile network configured by the MR 110, but a plurality of mobile terminals may be provided.

In addition, although only the mobile network configured by the MR 110 is illustrated in FIG. 1, the mobile network configured by the MR may be included in another mobile network to form an overlapped mobile network. Therefore, although not shown in FIG. 1, the HIP network system may further include upper mobile routers and terminals constituting a higher mobile network of the mobile network configured by the MR 110. A detailed description of the overlapped mobile network will be described later with reference to FIG. 2.

2 is a diagram illustrating an example of an HIP overlapping mobile network environment.

The overlapping mobile network means a network in which a network formed by an arbitrary MR is included in a network formed by another MR to form a nested mobile network.

The HIP overlapping mobile network of FIG. 2 includes mobile terminals MN ₁ , MN ₂ , MN ₃ , MN ₄ and MN ₅ , mobile routers MR ₀ and MR ₁ , Corresponding Node (hereinafter CN), Access Router (hereinafter AR) and RVS It includes. The general description of the mobile terminal MN, the mobile router MR and RVS is as described above with reference to FIG. 1.

Referring to FIG. 2, the mobile network of MR ₁ is contained in the mobile network of MR ₀ , which is an upper mobile network, so the overlapping degree of the mobile network of MR ₁ is 2. At this time, for MR ₀ , MR ₁ is recognized as a mobile terminal MN, not a mobile router.

As the mobile network of MR ₁ is embedded in the mobile network of MR _0, the mobile network constituted by the mobile router MR ₀ includes mobile terminals MN ₁ , MN ₂ , MN ₃ , MN ₄ and MN ₅ .

CN is a device that establishes a connection with a terminal in a mobile network. AR is a router located at the edge of a fixed internet backbone network and can have both wireless and wired network interfaces. Through the wireless network interface, MN or MRs can be provided with a connection service to an Internet backbone network.

FIG. 3 is a diagram illustrating an example of a process of registering a terminal in an HIP overlapping mobile network with RVS.

Referring to FIG. 3, the mobile terminal MN ₄ transmits the HIP control message I1 to the RVS in order to register its identifier and the current location (ie, IP address) to the RVS.

At this time, the mobile router MR1 located on the path of MN ₄ and RVS receives the HIP control message I1. MR ₁ stores the HIT and IP address information of MN ₄ in SNI, and changes the sender address of HIP control message I1 to MR _1's own CoA ((1 in FIG. 3)).

Since the MR of the mobile network ₁ is a mobile network configuration implies that the MR ₀ configuration, and the MR is ₀ (Home Agent) of the MR HA ₁ in accordance with the DMM. Therefore, the mobile router MR ₁ delivers the HIP control message I1 to the upper mobile router MR ₀ .

MR ₀ similarly stores the HIT of MR ₄ and the IP address of the sender (that is, the IP address of MR ₁ ) in the SNI, and changes the sender address to CoA of MR ₀ (2 in FIG. 3).

As a result, the SNI is the MR ₁ a (IP address of the MN ₄ of HIT, MN ₄₎ storage, it is stored the MR ₀ SNI is (IP address of the HIT, MR ₁ of ₄ MN).

The RVS receiving the HIP control message I1 from MR ₀ transmits the HIP control message R1 in response. First, R1 will be delivered to the MR _0, MR ₀ is changed by searching the SNI based on the HIT record R1 in the recipient address of the R1 to the IP address of the MR _1. Therefore, R1 is transmitted to MR ₁ . Upon receiving R1, MR ₁ searches for an SNI based on the HIT in R1 and changes the recipient address of R1 to the IP address of MN ₄ . As a result, R1 is transmitted to MN ₄ .

The process of transmitting HIP control messages I2 and R2 is repeated in the same way as the process of transmitting I1 and R1.

As a result, the information stored in the RVS after processing up to R2 is (HIT of MN ₄ , IP address of MR ₀ ) (3 in FIG. 2). That is, the location of the terminal MN ₄ registered in the RVS is set to the IP address of the highest mobile router (ie MR ₀ ) of the mobile network to which the MN ₄ belongs.

4 is a diagram illustrating an example of a connection establishment process between a terminal and a node.

Referring to FIG. 4, CN1 transmits a HIP control message I1 to the RVS using the HIT of MN ₄ to establish a connection with the mobile terminal MN ₄ . The RVS stores mobile terminal MN ₄ registration information (HIT of MN ₄ and IP address of MR ₀ ). Therefore, in the RVS, since the IP address corresponding to the HIT of MN ₄ is the IP address of MR ₀ , I1 is transferred to MR ₀ (1 in FIG. 4).

MR ₀ likewise uses the HIT of MN ₄ in I1 to find the corresponding IP address in SNI. (HIT of MN ₄ , IP address of MR ₁ ) is stored in SNI of MR ₀ , so the recipient IP address of I1 is changed to the IP address of MR ₁ and transmitted (② in Fig. 4).

MR ₁ searches for SNI as in MR _0, and changes the receiver IP address of I1 to the IP address of MN ₄ corresponding to the HIT of MN ₄ and transmits it (3 in FIG. 4). Therefore, I1 is finally delivered to MN ₄ .

R1 is changed to the IP address of the MN _4, MR _1, the address of the sender MN As the through _{MR 0 4, MR 1, MR} 0 , as described above in the terminal registration process, to the RVS of Figure 3, finally R1 This is transmitted to CN ₁ (④, ⑤ in FIG. 4).

I2 and R2 are delivered in the same way as the delivery process of I1 and R1, respectively.

Also, when transmitting from the CN ₁ I2, determines the CN ₁ and the MN's IPv6 headers ₄ used as an identifier for identifying the connection of the flow label (⑥ in Fig. 4). The flow label of the IPv6 header is referred to when changing the recipient address for packet transmission from the MR to the mobile network terminal. Since it is necessary to ensure that the coexisting connections have different values, a flow label value is proposed in I2 and the format is confirmed in R2. The mobile routers MR ₁ and MR ₀ extract the flow label value included in R2 and record it as (sender HIT, receiver HIT, flow label) in the flow table and use it for data packet delivery (7, ⑧ in FIG. 4).

Since the flow label included in R2 during the connection establishment process is included in the IPv6 header of the data packet, CN ₁ and Movement located on the path of MN ₄ The routers MR ₁ and MR ₀ extract this and search the receiver HIT corresponding to the corresponding flow label in the Flow Table. move The routers MR ₁ and MR ₀ deliver data packets to IP addresses corresponding to the HIT retrieved from the SNI so that data can be exchanged.

 5 is a diagram illustrating an example of location update when the address of the mobile network is changed.

Referring to FIG. 5, the mobile network constituted by MR ₁ is included in the mobile network constituted by MR ₀ , and then moved to the mobile network constituted by MR ₂ . Accordingly, the access point of the mobile network configured by MR ₁ is changed.

When a mobile network having multiple mobile terminal MNs moves and the network address is changed, only the mobile router of the mobile network reconstructs CoA (ie, IP address) according to the network address of the changed network access point. Therefore, only the mobile router MR ₁ in FIG. 5 can recognize the address change and construct a new CoA, and the terminals MN ₃ and MN ₄ in the mobile network do not recognize the address change.

As described above with reference to FIG. 3, the location of the terminal in the mobile network is registered as the IP address of the mobile router in the mobile network. Therefore, when the mobile network to the mobile router MR ₁ configuration moves and registers the CoA of the mobile router MR ₁ MR ₁ changed RVS. Also, the mobile router MR ₁ updates the information of the RVS on behalf of the terminals MN ₃ and MN ₄ in the mobile network. To this end, MR ₁ transmits an MUPDATE message including the HIT of all terminals MN3 and MN ₄ in the mobile network served by the modified MR ₁ CoA and MR1 to the RVS.

In addition, the mobile router MR ₁ may notify the upper mobile router MR ₀ that the address of MR ₁ has been changed by sending a NEMOupdate message including the changed MR ₁ CoA.

MR, like general MNs, registers its HIT and IP address in RVS, creates an HIP connection with RVS, and sends MUPDATE using this connection.

Accordingly, in the MUPDATE message sent from the MR to the RVS, the sender address change processing is performed in the upper mobile router of the upper mobile network, similar to the registration process of the MN in FIG. 3 to the RVS.

6 is a diagram illustrating an example of a location update and a data transmission path when an address of a terminal in a mobile network is changed.

6 is a location update and data transfer path when the mobile terminal MN ₄ moves from the mobile network of MR ₁ to AR ₂ .

The mobile terminal MN ₄ detects that it is connected to the new network by receiving the RA message sent by AR ₂ and newly sets the CoA of MN ₄ . And, the mobile terminal MN ₄ is moved to around the MN existing HA (Home Agent) of ₄ Binding update that contains the changed CoA of the MN ₄ to MR ₁ (hereinafter, BU) by sending a message register that location self changing the MN ₄ do.

In addition, MR ₁ received the BU message is a message to the parent mobile router MR ₀ of, MR ₁ so that data may be transmitted to the latest location of the MN ₄ according to the connection to the existing MN ₄ contains the changed CoA of the MN ₄ NEMOupdate To send. (1 in Fig. 6).

MN ₄ has been the locator information change process proceeds to register the changed position of the MN ₄ RVS. If the connection between MN ₄ and RVS is already established, a HIP UPDATE message is sent. If the connection to the RVS is not established, the terminal registration process to the RVS is first performed. At this time, since AR ₂ is not an MR and does not understand HIP, the original messages are exchanged without changes to HIP messages transmitted by MN ₄ .

Since the connection with CN ₁ was established before the movement of MN ₄ to AR ₂ , the data packet from CN ₁ to MN ₄ is transferred to MR ₀ . Since MR ₀ obtains the current IP address information of MN ₄ from MR ₁ , the data packet is delivered to AR ₂ , and ultimately the data packet is delivered to MN ₄ (dotted line in FIG. 6).

After moving MN ₄ to AR ₂ , CN ₂ sends an I1 message to RVS to establish a connection with MN4. Since RVS knows the latest CoA of MN ₄ , it sends an I1 message to MN ₄ to complete the 4-way handshaking process of HIP. Therefore, the data packet is directly delivered to MN ₄ via AR ₂ (solid line in FIG. 6). That is, the connection setting after the movement is made of the optimal path corresponding to the location after the movement.

7 is a flowchart illustrating an example of a process of registering a terminal in a HIP network with HIP RVS.

In step s710, the mobile router in the mobile network receives a control message to be transmitted from the terminal to the Host Identity Protocol (HIP) Rendezvous Server (RVS).

The terminal transmits a HIP control message to the RVS in order to register its identifier and current location (ie, IP address) to the RVS. Since the HIP control message is implemented as an extension header of IPv6, it is possible for the mobile router located on the path of the terminal and the RVS to overhear the HIP control message. Accordingly, the mobile router can receive a control message to be transmitted to the RVS from the terminal.

In step s720, the mobile router stores the HIT (Host Identity Tag) of the terminal and the IP address of the terminal from the control message.

(HIT of the terminal, IP address of the terminal) is stored in the SNI database of the mobile router.

 In step s730, the mobile router updates the control message by changing the IP address of the stored terminal to a Care-of-Address (CoA) of the mobile router.

 In step s740, the mobile router transmits the updated control message to the HIP RVS.

The RVS receiving the updated control message stores the terminal's registration information (the terminal's HIT and the mobile router's IP address).

So far, the present invention has been focused on the preferred embodiments. Those skilled in the art to which the present invention pertains will appreciate that the present invention may be implemented in a modified form without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments should be considered in terms of explanation, not limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the equivalent range should be interpreted as being included in the present invention.

Claims (11)

In the communication method of the HIP network,
A mobile router in a mobile network receiving a control message to be transmitted from a terminal to a Host Identity Protocol (HIP) Rendezvous Server (RVS);
Storing a host identity tag (HIT) of the terminal and an IP address of the terminal from the control message;
Updating the control message by changing the IP address of the stored terminal to a Care-of-Address (CoA) of the mobile router; And
And transmitting the updated control message to the HIP RVS.
The step of transmitting the updated control message to the HIP RVS,
When the mobile network belongs to a higher mobile network,
Transmitting, by the mobile router, the updated control message to an upper mobile router of the upper mobile network;
Storing, by the upper mobile router, the HIT of the terminal and the IP address of the mobile router from the updated control message;
Updating the control message by changing the IP address of the stored mobile router to a Care-of-Address (CoA) of the upper mobile router by the upper mobile router; And
And the upper mobile router transmitting the re-updated control message to the HIP RVS.
The mobile router is treated as a terminal to the upper mobile router, the communication method of the HIP network. delete According to claim 1,
When the address of the mobile network is changed,
And the mobile router of the mobile network transmitting a NEMOupdate message including the changed CoA of the mobile network to the upper mobile router. According to claim 1,
When the terminal in the mobile network is moved to another mobile network and the address of the terminal is changed,
And transmitting, by the terminal, a BU message including the changed CoA of the terminal to the mobile router of the mobile network. According to claim 1,
When the terminal in the mobile network is moved to another mobile network and the address of the terminal is changed,
And the mobile router of the mobile network transmitting a NEMOupdate message including the changed CoA of the terminal to the upper mobile router. According to claim 1,
When the address of the mobile network is changed,
And the mobile router transmitting a MUPDATE message including the changed CoA of the mobile router and the HIT of all terminals in the mobile network to the HIP RVS. According to claim 1,
A control message I1 including the HIT of the terminal transmitted by a CN (correspondent node) is transmitted to the terminal through HIP RVS;
Transmitting a control message R1 transmitted by the terminal to the CN;
Transmitting the control message I2 transmitted by the CN to the terminal; and
Further comprising the step of transmitting the control message R2 transmitted by the terminal to the CN, HIP network communication method. The method of claim 7,
The control message I1 including the HIT of the terminal transmitted by the CN (correspondent node) is transmitted to the terminal through the HIP RVS,
Receiving, by the mobile router, a control message I1 transmitted by the HIP RVS based on the registration information of the terminal stored in the HIP RVS; and
And the mobile router transmitting a control message I1 to the terminal based on the HIT of the terminal and the IP address of the terminal stored in the mobile router. The method of claim 7,
In the step of transmitting the control message I2 transmitted by the CN to the terminal, the CN determines a flow label of an IPv6 header that is an identifier for identifying the connection between the CN and the terminal,
In the step of transmitting the control message R2 transmitted from the terminal to the CN, the mobile router stores a flow label of the IPv6 header in a flow table. The method of claim 9,
And exchanging data between the CN and the terminal using a flow label of the IPv6 header. In the HIP (Host Identity Protocol) network system,
HIP Rendezvous Server (RVS);
Terminal; and
Mobile router; and
The mobile router,
Receiving a control message to be transmitted to the HIP RVS from the terminal, storing the host identity tag (HIT) of the terminal and the IP address of the terminal from the control message, and the IP address of the stored terminal CoA (Care of the mobile router) -of-Address) to update the control message, send the updated control message to the HIP RVS,
When the mobile network to which the mobile router belongs belongs to an upper mobile network,
The mobile router,
Transmitting the updated control message to an upper mobile router of the upper mobile network,
The upper mobile router,
Save the HIT of the terminal and the IP address of the mobile router from the updated control message,
Re-update the control message by changing the IP address of the stored mobile router to Care-of-Address (CoA) of the upper mobile router,
Transmits the re-updated control message to the HIP RVS,
The mobile router is treated as a terminal to the upper mobile router, HIP network system.

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