KR100811308B1 - Methods and system for end-to-end fast mobility management for multi-party real-time multimedia service in wireless networks - Google Patents

Abstract

A system and a method for managing end-to-end fast mobility for a multi-party real-time multimedia service in a wireless network are provided to support the IP based multi-party real-time multimedia service efficiently without knots irrespective of the kind of the wireless network when various mobile hosts move between homogeneous or heterogeneous cells. To provide a knotless IP(Internet Protocol) mobility managing function irrespective of the kind of upper transportation layer and application layer protocols in a wireless network, end-to-end call setup is performing by accessing a distributed type mobility managing system. And then, data is transceived by constructing a bidirectional packet transmission tunnel. When a mobile host moves between cells to enter a new subnet, a new temporary IP address is previously ensured in order to perform a knotless fast handover function in a real time multimedia service. When the mobile host moves and lower data link handover is completed, a new bidirectional tunnel for end-to-end data transmission is constructed by using the previously-ensured new temporary IP address. After that, data is transceived.

Description

End-to-end fast mobility management system and method for multi-party real-time multimedia service in wireless network {Methods and System for End-To-End Fast Mobility Management for Multi-Party Real-time Multimedia Service in Wireless Networks}

1: SMMP system structure according to the present invention

2: mobility support mechanism of SMMP according to the present invention

3: End-to-end mobility management procedure using the SMMP protocol according to the present invention

4: MIH-based SMMP early handover algorithm according to the present invention

5 is a signal message flow chart applying the early handover algorithm according to the present invention.

6: Multilateral mobility management algorithm according to the present invention

7: SMMP mobility management embodiment according to the present invention

8: P2P-based multi-party group communication configuration procedure according to the present invention

According to the present invention, when a mobile host moves between wireless cells in a wireless network, a real-time video conferencing based on voice over internet protocol (VoIP) or internet protocol (IP), and multi-party real time such as IPTV, without service disruption. The present invention relates to an end-to-end fast mobility management method and system capable of efficiently supporting a multimedia service (Multi-Party Real-Time Multimedia Service). The wireless network mainly means, but is not limited to, a wireless LAN (Local Area Network) or a wireless MAN (Metropolitan Area Network).

Looking at the related arts related to the present invention, the use of IP-based mobile real-time multimedia services such as mobile VoIP, mobile IPTV, and mobile real-time video conferencing has been rapidly increasing in developed countries such as the United States. Broadband Wireless LAN / MAN system represented by WiFi and WiMAX and B3G and 4G system supporting All-IP are actively researched and developed all over the world. Although these next-generation mobile communication systems have high-speed packet transmission, there is a problem in that a mobile terminal cannot provide a seamless high-speed handover function for providing a real-time multimedia service when moving between homogeneous or different wireless networks.

Looking at the technology for providing a seamless handover without interruption of service when the mobile terminal moves between cells in the wireless network, IETF SIP, an Internet standardization organization, to support end-to-end mobility in the application layer There is the Session Initiation Protocol (SIP) proposed by the WG, SCTP-ADDIP, which is being studied by IETF TAWG, and TCP Migrate developed by MIT University, to support end-to-end mobility in the transport layer. have. There are also MIPv4 of IETF MIP4 WG and MIPv6 of MIP6 WG for mobility support at the network layer. In addition, there are FMIPv4 / v6 and HMIPv6 for providing high speed handover based on MIP (Mobile IP) in IETF MISHOP WG. In addition, there is Network Mobility Basic Support Protocol (NMBSP) developed for mobility support when the entire network moves in IETF NEMO WG. In addition, in the link layer, the IEEE 802.11 WiFi and IEEE 802.16 WiMax WG groups are developing various standard two-layer handover technologies in terms of mobility management. In addition, IEEE 802.21 developed MIH (Media Independent Handover), an integrated two-layer handover interface that can be commonly applied to cellular networks such as WLAN, WMAN, CDMA, and GSM. In addition, 3GPP / 3GPP2 is developing handover technology unique to CDMA and GSM-based cellular networks.

However, even though so many various international standard protocols have been developed for mobility management, mobility management functions, which are essential for real-time mobile multimedia services, have not been smoothly supported in wireless IP communication networks. The reason is that network layer handover protocols such as MIP, FMIP, HMIP and NMBSP are implemented on a large scale because they require not only mobile terminals but also changes to existing network infrastructure (eg, router function modification). it's difficult. For example, in case of MIPv4 series, Home Agent and Foreign Agent should be newly installed in the network. In the case of the MIPv6 series, that is, MIPv6, FMIPv6, and HMIPv6, the home agent must be additionally installed in the existing IPv6 network. Installing new equipment in addition to existing networks is time-consuming and expensive.

To solve this problem, a technology to support mobility management in an end-to-end manner, that is, peer-to-peer (P2P) has been developed without modifying the existing network infrastructure. One of them is an attempt to provide a seamless handover function to a mobile terminal by extending the SIP protocol developed by the IETF developed for establishing a multimedia communication session. However, SIP has a problem in that the service is stopped while moving for the TCP-based application service. In addition, if the mobile station does not complete the new session setup by changing its IP address while in the overlapping region of the two cells, excessive packet loss may result in service interruption. In addition, there are problems such as NAT / Firewall traversal problem and micro-mobility support requiring high-speed handover. Recently, as a scheme for providing end-to-end mobility management in the transport layer, technologies such as TCP Migrate and SCTP-ADDIP have been developed. However, the biggest problem of the transport layer mobility management technology is that although it is not necessary to modify the network infrastructure, it is difficult to be widely applied because it is necessary to modify the existing installed applications. In conclusion, due to the above reasons, the existing network change and application limitation problem, even though many technologies and international standards have been developed so far, end-to-end wireless network IP mobility management is not properly provided to users. to be.

The technical problem to be achieved by the present invention is to solve the problems of the prior art as described above, a variety of mobile terminals such as mobile phones, Internet phones, smart phones, laptops in a wireless network between the same or heterogeneous wireless network cells Its purpose is to provide end-to-end high-speed mobility management that can efficiently support IP-based multi-party real-time multimedia services regardless of the type of wireless network.

It is still another object of the present invention to dynamically create end-to-end two-way tunnels using temporary IP addresses while communicating with the original IP addresses to which mobile stations are assigned, thereby enabling endless end-to-end IP mobility independent of upper transport and application layers. To provide management structure and functionality.

It is still another object of the present invention to find a temporary IP address by using L2 handover prediction function supported by the IEEE MIH standard or other L2 (Layer 2: Layer 2) before L2 handover is started. 3: Layer 3) By starting the handover function, it is to perform fast mobility management without packet loss or time delay due to handover.

Another object of the present invention is to provide a scalable P2P based multi-party mobility management method that can reduce excessive signaling overhead that may occur due to frequent movement of mobile terminals in multi-party group calls.

Another object of the present invention is to propose an end-to-end IP mobility management structure applicable to both IPv4 and IPv6 networks.

The present invention provides high-speed mobility that can efficiently support various multi-party real-time mobile multimedia services such as VoIP, IPTV, and IP-based video conferencing when a mobile terminal moves between cells in a wireless network. It relates to management methods and systems.

Hereinafter, the configuration and operation of the embodiments of the present invention with reference to the accompanying drawings, the configuration and operation of the present invention shown and described in the drawings will be described by at least one embodiment, whereby the present invention described above The technical idea and its core composition and operation are not limited.

With reference to the drawings shown so that the present invention can be easily understood. 1 illustrates a structure of a Simple Mobility Management Protocol (SMMP) system. 2 illustrates the mobility support mechanism of the SMMP. 3 illustrates an end-to-end mobility management procedure using the SMMP protocol. 4 illustrates a MIH based SMMP early handover algorithm. 5 shows a signal message flow chart applying the early handover algorithm. 6 illustrates a multiparty mobility management algorithm. 7 illustrates an embodiment of SMMP mobility management. Finally, Figure 8 shows a P2P-based multi-party group communication configuration procedure.

1 shows an SMMP system structure for realizing end-to-end fast mobility management for a multi-party real-time multimedia service proposed in the present invention. SMMP system is divided into SMMP (Simple Mobility Management Protocol), mobility management protocol, DMMT (Distributed Mobility Management Table) which stores user location and group mobility management information, and DGMT (Distributed Group) which is distributed group management table. Management Table) and DMMS (Distributed Mobility Management System) which is a distributed mobility management system for managing DMMT and DGMT. In addition, there is an LBC (Local Binding Cache) that stores mobility management information locally in a mobile terminal.

SMMP stores and manages the user's location information, mobility management service requirements, and group communication information in DMMT, and provides end-to-end 1: 1 call setup or group call and provides seamless handovers so that there is no service disconnection when moving. It is a great mobility management protocol. Distributed mobility management system (DMMS) is a distributed database system that stores and manages mobility management information. Distributed mobility management system can be implemented in various ways such as various commercial distributed database system, SIP server system, LDAP server or dedicated P2P server. In the present invention, the detailed implementation method of the distributed mobility management system is not mentioned.

In FIG. 1, the SMMP may provide a stable end-to-end mobility management function by interworking with the L5 (Layer 5) Internet protocol from L2 (Layer 2). SMMP is installed in end-to-end mobile terminal to perform L3 real-time high speed handover function. SMMP's real-time, high-speed handover is interoperable with L2 MIH interfaces or L2 handover systems with similar functionality. SMMP can reduce the overhead of establishing L3 tunneling by differentiating whether the upper protocol is UDP or TCP by interworking with L4 (Layer 4) transport layer. SMMP can safely set up calls using L5's various application protocols (eg Secure HTTP or Secure SIP).

SMMP supports terminal mobility, user mobility, and service mobility. DMMT consists of UserID for user mobility management, A_Addr, which is an assigned IP address, and T_Addr, which is a temporary IP address temporarily assigned to a user during movement or roaming. In addition, there are Group_ID for group communication, Security Class for secure mobility management, and S_Class (Service and Security Class) for determining QoS. S_Class determines QoS (Quality of Service) such as tunnel encryption method and handover delay time or handover delay time in end-to-end data transmission. The location information indicates the user's current geographical location and can perform mobility management functions related to the location. This is optional. SMMP provides User Mobility that allows User to perform Mobility Management function independently of the type of mobile terminal by using UserID. Also, A_Addr and T_Addr are used to provide terminal mobility that supports seamless connectivity even when a mobile terminal moves between cells. Finally, S_Class and Service Profile can be used to provide service mobility. The SMMP system architecture of FIG. 1 is applicable to both IPv4 and IPv6. This is because A_Addr and T_Addr associated with an IP address do not require specific IPv6 functionality.

The Distributed Group Management Table (DGMT) is a table for managing various user and multi-party communication groups in a distributed environment. DGMT may be configured in a distributed hierarchical manner, and provides grouping information for grouping users to configure various user-based mobile services. The custodian is responsible for the registration, operation and management of the group. The initiator is responsible for creating, operating and supporting multi-media multimedia group service sessions. The member list contains a list of users belonging to the group. In the case of hierarchical DGMT, the subgroup list includes information. The service profile includes information related to a specific application service provided by Group_ID. For example, it describes the features of various real-time mobile multimedia services such as 1: 1 internet phone or video communication, remote multimedia lecture, multi-party video conferencing, remote multi-line online game, multi-party text chat, multi-party video sharing. Users can participate in a particular service of interest with reference to the DGMT. The location information indicates the current geographical location of the group starter providing the service and is optional. LBC (Local Binding Cache) is a high-speed temporary information store that stores and manages mobility management information locally in order to maintain end-to-end seamless session connection even between mobile devices. The information stored in the LBC includes the lifetime of the T_Addr, along with the UserID, A_Addr, and T_Addr of the self and the counterpart.

FIG. 2 illustrates a basic mobility management scenario of SMMP based on the structure of the SMMP system of FIG. 1. In FIG. 2, the mobile terminal first pre-registers in the distributed mobility management table. When the mobile terminal A wants to communicate with the mobile terminal B, it sends a call setup request message① to the mobile terminal B through the distributed mobility management system. Mobile terminal B sends a call setup response message ② to mobile terminal A through the distributed mobility management system. A and B send and receive a call setup message and then establish a two-way tunnel to send and receive data. Here, A_Addr is used as an IP address for transmitting and receiving A and B, and T_Addr, a temporary IP address, is used as an entry address and exit address of a bidirectional tunnel.

Consider the case where mobile terminal A moves from subnet 1 to subnet 2. As shown in FIG. 2, when the mobile terminal B moves to the radio overlap regions of subnets 1 and 2, terminal movement is reported by a layer 2 handover function. Mobile B acquires a new temporary IP address for use in Subnet 2 as soon as possible when it receives a terminal handover notification by Layer 2 handover, and immediately updates the binding address to the other mobile A when it receives an L2 handover termination report. It sends a request message ③ to notify the change of the temporary IP address and sends and receives data to the new tunnel with the new temporary IP address. The re-registration request message ④ is used to notify the distributed mobility management system of the change of the temporary IP address. The distributed mobility management system modifies T_Addr in user A's distributed mobility management table and sends a re-registration response message ⑤ to the distributed mobility management system to complete the handover operation.

Here, it is necessary to acquire a new temporary IP address to provide a real-time multimedia service such as VoIP without disconnection or deterioration of service quality while moving, that is, a knot-free handover function. However, it usually takes 1-2 seconds to assign a new IP address, so SMMP uses Early Handover technology to reduce this. Early handover technology uses the IEEE MIH service or similar L2 handover service to allow L3 handover operation to start before L2 handover is terminated. This enables high-speed handover between heterogeneous and homogeneous networks.

In Figure 2, the mobile terminal does not necessarily have to be mobile. It could be a fixed server, a desktop computer, or various ubiquitous terminals. When moving from subnet 1 to subnet 2, if the mobile station's IP address does not change, it uses the pass-through function to communicate without establishing a tunnel. The mobile environment is basically vulnerable to external intrusion such as eavesdropping, so if you want to enhance the security of data transmission and reception between both ends, you can use the IPSec function to enhance the security of data transmission and reception. When accessing the distributed mobility management system, registration and re-registration messages and call setup messages can be encrypted and transmitted to prevent connection hijacking or remote-redirection attack. . In addition, the call setup can be performed more safely by using 3-Way Handshake. Other combined address update messages can also be encrypted and sent. In the case of a joint address update message, a high speed transmission and processing is required, so a fast encryption method is required. Since SMMP basically seeks simplicity in structure and operation, the security method for call setup and binding address update messages is treated as an option of SMMP protocol.

3 shows an end-to-end mobility management procedure for a multi-party multimedia service using the SMMP protocol. In FIG. 3, a user registers UserID, A_Addr, and T_Addr with DMMT using a registration request message. If you want group communication, register Group_ID of subscribed group. When the user wants end-to-end multimedia communication, he / she sends his / her counterpart UserID and his current T_Addr and QoS and security requirements related to call setup in the call setup request message to DMMS. If a group communication is required, the group service profile is also sent. DMMS registers call request in DMMT by referring to call setup request message and delivers call setup request message to requested end user. If the call setup succeeds, the user refers to the mobility management information received from the other party, creates a bidirectional tunnel for data transmission and reception, and then exchanges data. In this case, data can be exchanged securely in accordance with security requirements negotiated between the two ends.

When mobile terminal movement is detected between cells during communication, early handover technology is applied to acquire a new temporary IP address in advance, and a new data transmission tunnel can be quickly established for use in the moved cell, thus reducing packet loss or time delay due to handover. Eliminate The DMMS notifies the DMMS of the change of the new temporary IP address to complete the handover operation. In FIG. 3, when setting up a group call, a user may specify an application layer protocol requirement or a transport layer requirement necessary for multilateral group communication by referring to an application layer and a transport layer protocol of a mobile terminal as shown in FIG. 1. Other user registration, call setup and address update messages can also be sent securely using international standard data encryption technology.

4 illustrates a MIH based SMMP early handover algorithm. In FIG. 4, Link Going Down and Link Up are triggers related to L2 handover provided by MIH, and a neighbor map can be obtained using MIH information service. The selection of the candidate access point may be determined by measuring received radio wave strength or by using location information. In FIG. 4, the link going down indicates that a mobile terminal is moving and soon handover occurs. In this case, the mobile station examines the Router Advertisement message and uses the automatic address generation function or accesses a DHCP server to obtain a new temporary address (new T_Addr) for use in the new subnet. Immediately after L2 handover is performed, the L3 handover latency is minimized by changing the IP / MAC address mapping table of the new AP and the new router to complete the L3 handover. Early handover means that the mobile terminal starts the L3 handover early before the L2 handover is completed. This significantly reduces handover latency.

Figure 5 shows a signal message flow chart applying the above SMMP early handover algorithm. In FIG. 5, the mobile station B waits for a new T_Addr address to be used in the newly moved subnet by connecting to a DHCP server or using an IPv6 auto-configuration function when a handover trigger command from L2 occurs. . When the handover complete signal is received from L2, a new T_Addr is immediately transmitted to the mobile station B and the DMMS using the address combination update request message. The mobile station B establishes a new tunnel immediately after receiving the address combination update request message and transmits the address combination update response message to the mobile station B. Mobile terminal A then transmits data to the new tunnel. When the mobile station B receives the address combination update response message from A, it receives data from the old tunnel in use by using the new T_Addr obtained from the DHCP server. At this time, if the mobile station B operates in the duplex mode, it can continue to receive data coming to the old tunnel, thereby eliminating packet loss due to handover. As mentioned earlier, the early handover algorithm receives a handover prediction signal from L2 and starts the L3 handover before the L2 handover ends and acquires T_Addr in advance, so that it is associated with Duplicate Address Detection (DAD) or DHCP server access. L3 handover time delay can be eliminated. In the case of the terminal operating in dual mode, packet loss due to handover can be reduced because the data can still be received in the new old tunnel after the address combination update response message is sent. However, a packet loss arrives at the old T_Addr after the mobile terminal crosses the radio overlapping region. However, in this case, recovery is possible at the upper TCP layer. However, in case of time service traffic using UDP, packet loss may occur due to network layer congestion. In FIG. 5, the combined address update response message is optional and is sent to the new T_Addr.

6 is a multi-party mobility management algorithm for supporting M: N communication rather than 1: 1 for a plurality of mobile terminals. First, the mobile terminal requests registration to a specific communication group from the DMMT of the DMMS. If the mobile station wants to set up real-time group communication for a specific group to which it belongs, it sends a real-time group call setup request message to the DMMS with the corresponding Group_ID. After receiving the group communication setup request from the mobile station, the DMMS retrieves the DMMT and sends an end-to-end call setup message on behalf of the group communication call initiator to all mobile terminals registered to the corresponding Group_ID. In this case, IP can be used to support multicasting to reduce signal overhead. The mobile terminal receiving the group call setup message from the DMMS notifies the DMMS of participation. The DMMS delivers a call setup response message for group communication received from the mobile terminal to the call originator. The mobile terminal that initiated the call, that is, the call originator, establishes a two-way tunnel with each mobile terminal that wants to participate in group communication by referring to the response received from the DMMS.

The group call initiator is responsible for managing group calls between all mobile terminals participating in the group. If the mobile terminal participating in the group call moves, it is not necessary to change the tunnel with other mobile terminals participating in the group, but only change the originator and the data tunnel. In this way, signaling overhead due to the movement of the mobile station can be reduced even in a M: N multi-party group call. Of course, when the starter moves, signaling overhead according to the movement may occur in all terminals participating in the group call. In general, the starter should be able to manage M: N group communication, so it is preferable to use a high-performance system that is rich in CPU performance or memory capacity. Moreover, it is preferable to deploy in a system that does not move frequently to reduce signaling overhead. Do. Look at the embodiment according to the present invention.

An embodiment according to the present invention will be described with reference to the drawings. The end-to-end mobility management system and method for a multi-party real-time multimedia service in the wireless network proposed in the present invention is IEEE 802.11 wireless LAN, IEEE 802.16 wireless man other similar WLAN / man, wireless mesh network or wireless multi-hop, wireless sensor network and It can be applied to the next generation wired / wireless converged network connected with various heterogeneous wireless networks and homogeneous networks such as cellular networks. 7 shows an embodiment of mobility management of an entire system consisting of SMMP and DMMS / DMMT.

UserID와 고유 IP 주소 A_Addr 및 현재 임시주소 T_Addr을 분산이동성관리테이블에 등록한다. 그룹통신을 원할 경우 특정 그룹을 선택하여 관련된 Group_ID도 등록한다. 종단 사용자 A는 사용자 B와 멀티미디어 통신을 원할 경우 자기가 현재 사용하고 임 시 IP주소 T_Addr과 멀티미디어 통신의 특성에 따른 QoS요구사항, 보안요구사항 등을 실어서 DMMS에게 B와의 콜 설정요청메시지③을 보낸다. In FIG. 7, mobile terminals A and B use registration request messages ① and ②.

Register UserID, unique IP address A_Addr and current temporary address T_Addr in distributed mobility management table. If you want group communication, select specific group and register related Group_ID. If user A wants to communicate with user B, the user A uses the current IP address T_Addr and the QoS requirements and security requirements according to the characteristics of the multimedia communication. send.

The DMMS registers the relevant information in the DMMT from the call establishment request message and delivers the call establishment request message ④ from A to the user B. User B examines the call setup request from A and sends a call setup response message ⑤ including response to QoS and security setup and B's current temporary address T_Addr to DMMS. DMMS reflects the information received from user B to DMMT and forwards the call setup response message⑥ to user A. User A optionally sends a call setup confirmation message ⑦ to User B. In most cases, there is no need to send message⑦.

User A generates an IP packet of a sender IP address A_Addr and a receiver IP address B_Addr by referring to mobility management information received from B when the call setup response received from B is successful. As shown in FIG. 7, T_Addr of users A and B is transmitted to user B through a tunnel having an entry and exit address. In this case, if A_Addr and T_Addr are the same in both transmitting and receiving terminals, there is no need to form a tunnel since the two terminals A and B exist in the same subnet. However, if stronger security is required, data can be transmitted through tunnel after encrypting data using IPSec. In this way, SMMP provides various security levels not only for registration and call setup but also for data transmission, providing a method that allows users to transmit and receive data in real time flexibly and securely while on the move. In FIG. 7, the data received from the terminal B is decapsulated and then transmitted to the user B using the original allocated IP address A_Addr as the transceiver address. It should be noted here that protocols in the transmission and reception network are not distinguished, so both UDP and TCP are available.

The next time User B moves to another subnet, B must obtain a new IP address. In this case, user B updates the address combination information of A by sending an address combination update request message ⑧ to user A, which is currently communicating the new temporary IP address obtained during the move. After the user A receives the request for renewal of the address binding, the user B creates a new tunnel with the new temporary IP address. In some special cases, an address combination update response message ⑨ may be sent to user B. In FIG. 7, data from the mobile station A is transmitted through the newly formed tunnel without changing the IP address while the mobile station B moves. In case of SIP, a new IP address needs to be changed for mobility management. In case of a long TCP connection, a fatal flaw occurs. However, in case of SMMP, only a tunneling IP address is changed. Since the TCP port address can be maintained, the TCP problem can be eliminated. Finally, user B sends a re-registration request message to DMMS to change the current address of B registered in DMMT to a new T_Addr. DMMS sends a re-registration response message to mobile station B.

8 shows a P2P-based multi-party group communication configuration procedure. Mobile terminals A, B, C, and D belong to the same group, and user A sends a group call setup request message ① to the distributed mobility management system as a group initiator. The distributed mobility management system receives ① and sends a group call setup message ② to group members B, C and D. At this time, it can also be delivered using the multicasting function. Group members send a group call setup response message ③ to the distributed mobility management system. The distributed mobility management system sends a response message ④ to A, the group communication starter. Group members then exchange packets with A, the start of group communication, via a bidirectional communication tunnel. A, the group commencement, is responsible for the operation and management of group communications. Unlike the existing Internet portal, group members perform group communication using P2P method using the group initiator's IP address. In addition, the starter is responsible for managing the multiparty groupware application service for group communication. Of course, if the member moves, the handover between the moving member and the starting person is supported. In this way, SMMP supports M: N multi-party mobile multimedia service in mobile environment. Moreover, SMMP utilizes hierarchical group management table to provide service scalability to users and to join various mobile application service groups.

In the present invention, a scalable high-speed mobility management method and system suitable for multi-party real-time mobile multimedia services using bidirectional tunneling technology, P2P-based distributed group communication technology, and early handover technology are presented. In this case, when a mobile terminal moves between cells in a wireless network, a mobility management method capable of efficiently supporting IP-based multi-media real-time multimedia services regardless of the type of the wireless network, comprising: a) a mobile terminal moving between cells in a wireless network; In order to perform end-to-end mobility management structure and end-to-end mobility management consisting of mobile terminal, distributed mobility management table and distributed mobility management system for distributed mobility management table management under distributed environment, Mobile terminal in management system is distributed mobility management The system of the user ID UserID, assign a unique IP address of A_Addr, registering the currently used temporary IP address of T_Addr, position Group_ID, the mobile station assigns to a user for being stored; b) accessing a distributed mobility management system to support a real-time multimedia service independently of a higher transport layer protocol type in a wireless network, performing end-to-end call setup, and establishing a bidirectional packet transmission tunnel to transmit and receive data; c) acquiring a new temporary IP address in advance in order to perform a fast handover function without any knot in a real-time multimedia service such as VoIP when the mobile terminal enters a new subnet when moving between cells; And d) establishing a new two-way tunnel for end-to-end data transmission and transmitting data by using the new temporary IP address previously secured when the lower data link handover is completed when the mobile terminal moves.

Accessing the mobility management system to perform end-to-end call setup, and establishing a bidirectional packet transmission tunnel to transmit and receive data, the mobile terminal sends a call setup request message to the mobility management system to manage the mobility management. The system transmits a call setup request message to the counterpart mobile terminal, and the counterpart mobile terminal receiving the call setup request message transmits a call setup response message to the mobility management system, and the mobility management system delivers a call setup response message to the mobile terminal. After the call setup is completed, each mobile terminal configures a packet as an IP address for transmitting and receiving A_Addr and a bidirectional tunnel using T_Addr as an inlet and an outlet, respectively, to transmit and receive packets. Im new in advance to perform fast handovers without knots Obtaining the IP address involves using the handover information from the second layer according to the movement of the mobile node and accessing DHCP before the second layer handover is completed, or using the autoconfiguration function to obtain a new temporary IP address (T_Addr). It is secured in advance to prepare for the handover, and after the second layer handover is completed, the temporary IP address is transmitted to the other mobile terminal, characterized in that it consists of early handover to notify the mobility management system of the change of the new temporary address.

When the lower data link handover is completed, establishing a new bidirectional tunnel for end-to-end data transmission by using a new temporary IP address secured in advance and transmitting data includes a new terminal secured in advance by an early handover method. It transmits a temporary IP address to a counterpart mobile terminal and establishes a two-way tunnel using a new T_Addr as an inlet and an outlet between both ends to transmit and receive packets.It connects to the mobility management system to perform end-to-end call setup and establishes a bidirectional packet. In the step of establishing a transmission tunnel and transmitting / receiving data, in the step of transmitting a call setup request message to the mobility management system to the counterpart terminal to which the mobile terminal wants to talk, if the mobile station designates Group_ID registered by the mobile terminal user in the call setup request The mobility management system is the user of all members of Group_ID. The call setup request message is delivered to the mobile station user, and the mobile terminal user capable of group call delivers the call setup response message to the mobile terminal user who sent the group setup request message through the mobility management system, and then completes the call setup. The terminal configures a packet with a transmitting / receiving IP address, respectively, and configures a bidirectional tunnel using a T_Addr as an inlet and an outlet with a multiparty group communication initiator, and provides a multiparty group communication service while transmitting and receiving a packet.

In the step of providing the multi-party group communication service, a user who sends a group call setup request message becomes a group call starter and operates and manages a multi-party multimedia application service that can simultaneously participate in users participating in the group in the mobile terminal of the starter. It characterized in that to provide.

In summary, the invention of a high-speed mobility management system provides a mobility management system that can efficiently support IP based multi-party real-time multimedia services regardless of the type of wireless network when a mobile terminal moves between cells in a wireless network. When a mobile terminal moves between cells, the mobile terminal moves to perform end-to-end mobility management structure and end-to-end mobility management structure consisting of a mobile terminal, distributed mobility management table, and a distributed mobility management system for managing distributed mobility management table in a distributed environment. Terminal information to distributed mobility management system The mobile terminal uses user ID as user ID, A_Addr as assigned IP address, T_Addr as temporary IP address currently used, Group_ID as a user, and current mobile terminal location in distributed mobility management system. Means for registering and storing the; b) a means for accessing a distributed mobility management system to support various real-time multimedia services independently of upper transport layer protocol types in a wireless network, performing end-to-end call setup, establishing a bidirectional packet transmission tunnel, and transmitting and receiving data; c) means for acquiring a new temporary IP address in advance to perform a fast handover function that is seamless in real-time multimedia services such as VoIP when the mobile terminal enters a new subnet when moving between cells; And d) a means for establishing a new two-way tunnel for end-to-end data transmission and transmitting data by using a new temporary IP address secured in advance when the mobile terminal completes the lower data link handover.

The means for accessing the distributed mobility management system to perform end-to-end call setup and establishing a two-way packet transmission tunnel to transmit and receive data is a call setup request message to the mobile terminal to which the mobile terminal wants to talk. The distributed mobility management system sends a call setup request message to the counterpart mobile terminal, and the counterpart mobile terminal receiving the call setup request message sends a call setup response message to the distributed mobility management system. The call setup response message is delivered to the terminal to complete call setup. Each mobile terminal configures a packet by setting A_Addr as a sending / receiving IP address, and forms a bidirectional tunnel using T_Addr as an inlet and an outlet, respectively. It is characterized in that the high-end multimedia services such as VoIP In order to perform the handover function, the means for acquiring a new temporary IP address in advance may use the handover information from the second layer according to the movement of the mobile node to connect to DHCP or perform the address autoconfiguration function before the second layer handover is completed. The new temporary IP address (T_Addr) is secured in advance to prepare for the handover, and after the two-layer handover is completed, the temporary IP address is transmitted to the other mobile terminal, and the change of the new temporary address is distributed to the distributed mobility management system. It is characterized by having an early handover to notify.

The means for establishing a new two-way tunnel for end-to-end data transmission using the new temporary IP address secured in advance when the lower data link handover is completed and transmitting the data by the mobile terminal is newly secured by the early handover method. It transmits the temporary IP address to the other mobile terminal and establishes a two-way tunnel with a new T_Addr as an entrance and exit between both ends to transmit and receive packets.It connects to the distributed mobility management system to perform end-to-end call setup and bi-directionally. The means for establishing a packet transmission tunnel and transmitting / receiving data transmits a call setup request message to the distributed mobility management system to the counterpart mobile terminal to which the mobile terminal wants to talk, and the counterpart mobile terminal transmits the Group_ID registered by the mobile terminal user in the call setup request. If specified, the distributed mobility management system is a member of Group_ID. Call setup request message is sent to all mobile terminal users, and mobile terminal user capable of group call completes call setup by sending call setup response message to mobile terminal user who sent group setup request message through distributed mobility management system. After that, each mobile station constructs a packet using the A_Addr as a transmission / reception IP address, and configures a bidirectional tunnel using the T_Addr as an inlet and an outlet with a multiparty group communication initiator to transmit and receive packets while providing a multiparty group communication service. It is characterized by.

The means for providing the multi-party group communication service is the mobile terminal user who sends the group call setup request message to be the group call originator, and the operation and management of the multi-media multimedia application service that can simultaneously participate in the group's users in the mobile terminal of the initiator. It is configured to provide.

The present invention is a mobile phone, Internet phone, PMP in a wireless network. UltraPC. End-to-end high-speed mobility that can efficiently support IP-based multi-party real-time mobile multimedia services regardless of the type of wireless network when various mobile hosts such as smart phones and laptops move between homogeneous or heterogeneous cells Its industrial applicability is very high because it has the effect of giving management functions.

The present invention is a mobile phone, Internet phone, PMP in a wireless network. UltraPC. It provides end-to-end high-speed mobility management that can efficiently support IP-based multi-party real-time multimedia services regardless of the type of wireless network when various mobile terminals such as smartphones and laptops move between homogeneous or heterogeneous cells. It has an effect.

Another effect of the present invention is independent of the upper transmission and application layer by communicating with dynamically forming an end-to-end two-way tunnel with a temporary IP address with reference to the distributed mobility management system while the mobile is assigned with the original IP address assigned to the mobile station. It has the effect of providing end-to-end IP mobility management without knots.

Another effect of the present invention is to use the L2 handover start prediction function supported by the IEEE 802.21 MIH standard or other L2 in a method of finding a temporary IP address by referring to the distributed mobility management system before the L2 handover is started. By starting the L3 handover function, it has the effect of performing fast mobility management without packet loss or time delay due to handover.

Another effect of the present invention is to efficiently store and manage group management information in a distributed mobility management system and a mobile terminal, thereby reducing the signaling overhead that may occur due to frequent movement of a mobile terminal in P2P-based multi-party group communication. It has the effect of performing multimedia service mobility management.

Another effect of the present invention is to efficiently manage and manage P2P-based security and quality of service by efficiently storing and managing security and QoS information in a distributed mobility management system and a mobile terminal.

Another effect of the present invention is to present an end-to-end IP mobility management structure applicable to both IPv4 and IPv6 networks.

Claims (12)

In the mobility management method that can efficiently support IP-based multi-party real-time multimedia services regardless of the type of wireless network when the mobile terminal moves between cells in the wireless network, To perform end-to-end mobility management structure and end-to-end mobility management composed of distributed mobility management system for mobile terminal, distributed mobility management table and distributed mobility management table under distributed environment when mobile terminal moves between cells in wireless network Registering, by a mobile terminal user, a user ID as a user ID, an assigned unique IP address A_Addr, a temporary IP address T_Addr currently being used, a Group_ID subscribed by the user, and a location of a current mobile terminal in a distributed mobility management system; In order to provide IP mobility management function without knot independent of upper transport layer and application layer protocol type in wireless network, it connects to distributed mobility management system to perform end-to-end call setup and establish two-way packet transmission tunnel to transmit and receive data. step; When the mobile terminal enters a new subnet when moving between cells, acquiring a new temporary IP address in advance to perform a high-speed handover function that is free of real-time multimedia services such as VoIP; And And a step of establishing a new two-way tunnel for end-to-end data transmission and transmitting data by using a new temporary IP address previously secured when the lower data link handover is completed when the mobile terminal moves. The method according to claim 1, Accessing the distributed mobility management system to perform end-to-end call setup, and establishing a bidirectional packet transmission tunnel to transmit and receive data, sends a call setup request message to the mobility management system to the mobile terminal to which the mobile terminal wants to talk. The mobility management system transmits a call setup request message to the counterpart mobile terminal, and the counterpart mobile terminal receiving the call setup request message transmits a call setup response message to the distributed mobility management system so that the mobility management system responds to the call setup response. Call setup is completed by transmitting a message, and each mobile terminal configures a packet using A_Addr as a transmission / reception IP address, and configures a bidirectional data transmission tunnel using T_Addr as an inlet and an outlet, respectively. A great high speed mobility management method. The method according to claim 1, Acquiring a new temporary IP address in advance in order to perform a high speed handover function that is not knotted on the real-time multimedia service such as VoIP is performed by using the handover information from the second layer according to the movement of the mobile node. Prepare a handover by accessing a DHCP server or by using the autoconfiguration function to obtain a new temporary IP address (T_Addr) in advance.After the two-layer handover is completed, the temporary IP address is immediately transmitted to the other mobile terminal. An end-to-end fast mobility management method comprising an early handover for notifying the mobility management system of the change of a new temporary address. The method according to claim 1, When the lower data link handover is completed, establishing a new bidirectional tunnel for end-to-end data transmission by using a new temporary IP address secured in advance and transmitting data includes a new terminal secured in advance by an early handover method. End-to-end fast mobility management method characterized in that the transmission of the temporary IP address to the other mobile terminal to establish a two-way tunnel using a new T_Addr as the entry and exit between both ends to send and receive packets. The method according to claim 1 or 3, Accessing the distributed mobility management system to perform end-to-end call setup and establishing a bidirectional packet transmission tunnel to transmit and receive data, the mobile terminal transmits a call setup request message to the counterpart terminal to which the mobile terminal wants to talk. If the mobile station specifies the Group_ID registered by the mobile station user in the call setup request, the distributed mobility management system delivers the call setup request message to all the users belonging to the Group_ID. After completing the call setup by transmitting the setup response message to the mobile terminal user who sent the group setup request message through the distributed mobility management system, each mobile terminal constructs a packet using A_Addr as the transmission / reception IP address. Multi-way group communication initiator with T_Addr as an entrance and exit Point-to-point high-speed mobility management method characterized in that, while sex and receive a packet provided a multi-party group communication service. The method according to claim 5, In the step of providing the multi-party group communication service, a user who sends a group call setup request message becomes a group call starter and operates and manages a multi-party multimedia application service that can be simultaneously joined to users participating in the group in the mobile terminal of the starter. End-to-end high speed mobility management method, characterized in that to provide. In a mobility management system that can efficiently support IP-based multi-party real-time multimedia services regardless of the type of wireless network when the mobile terminal moves between cells in a wireless network, To perform end-to-end mobility management structure and end-to-end mobility management composed of distributed mobility management system for mobile terminal, distributed mobility management table and distributed mobility management table under distributed environment when mobile terminal moves between cells in wireless network The mobile terminal user registers and stores the user ID UserID, the assigned unique IP address A_Addr, the temporary IP address T_Addr currently used, the Group_ID to which the user is registered, and the location of the current mobile terminal in the distributed mobility management system. In order to provide IP mobility management function that is independent of upper transport layer and application layer protocol type in wireless network, it connects to distributed mobility management system to perform end-to-end call setup and establish two-way packet transmission tunnel to send and receive data Means to Means for securing a new temporary IP address in advance in order to perform a high speed handover function without any knot in real-time multimedia services such as VoIP when the mobile terminal enters a new subnet when moving between cells; And a means for establishing a new two-way tunnel for end-to-end data transmission and transmitting data by using a new temporary IP address previously secured when the lower data link handover is completed when the mobile terminal moves. The method according to claim 7, The means for accessing the distributed mobility management system to perform end-to-end call setup, establishing a bidirectional packet transmission tunnel, and transmitting and receiving data sends a call setup request message to the mobility management system to the mobile terminal to which the mobile terminal wants to talk. The mobility management system transmits a call setup request message to the counterpart mobile terminal, and the counterpart mobile terminal receiving the call setup request message transmits a call setup response message to the distributed mobility management system so that the mobility management system responds to the call setup response. Call setup is completed by transmitting a message, and each mobile terminal configures a packet using A_Addr as a transmission / reception IP address, and configures a bidirectional data transmission tunnel using T_Addr as an inlet and an outlet, respectively. Great high speed mobility management system. The method according to claim 7, The means for securing a new temporary IP address in advance in order to perform a high speed handover function such as the VoIP real-time multimedia service is completed by using the handover information from the second layer according to the movement of the mobile node. Prepare a handover by accessing a DHCP server or by using the autoconfiguration function to obtain a new temporary IP address (T_Addr) in advance.After the two-layer handover is completed, the temporary IP address is immediately transmitted to the other mobile terminal. An end-to-end fast mobility management system comprising an early handover for notifying the mobility management system of the change of a new temporary address. The method according to claim 7, The means for establishing a new two-way tunnel for end-to-end data transmission using the new temporary IP address secured in advance when the lower data link handover is completed and transmitting the data by the mobile terminal is newly secured by the early handover method. End-to-end high-speed mobility management system, characterized in that by sending a temporary IP address to the other mobile terminal to establish a two-way tunnel using a new T_Addr as an entry and exit between the two ends. The method according to claim 7 or 8, The means for accessing the distributed mobility management system to perform end-to-end call setup and establishing a two-way packet transmission tunnel to transmit and receive data transmits a call setup request message to a counterpart terminal to which the mobile terminal wants to talk. If the mobile station specifies the Group_ID registered by the mobile station user in the call setup request, the distributed mobility management system delivers the call setup request message to all the users belonging to the Group_ID. After completing the call setup by transmitting the setup response message to the mobile terminal user who sent the group setup request message through the distributed mobility management system, each mobile terminal constructs a packet using A_Addr as the transmission / reception IP address, and each T_Addr The multi-way group communication initiator using Castle by point-to-point high-speed mobility management system and send and receive packets, characterized in that to provide a multi-party group communication service. The method according to claim 11, The means for providing the multi-party group communication service is a user who sends a group call setup request message at this time, and the operation and management of the multi-party multimedia application service that can be simultaneously joined to the users participating in the group in the mobile terminal of the initiator. End-to-end high speed mobility management system, characterized in that to provide.

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