KR101491979B1 - A vertical handover system for maritime multi-band networks and a method thereof - Google Patents

Abstract

The present invention relates to a vertical handover system for maritime multi-band network, and a method thereof to propose a logic structure and reference communication model for a vertical handover applicable to a maritime multi-band network enabling a seamless communication during a heterogeneous handover by a maritime multi-band system by redefining related instructions. Accordingly, a time taken by a ship station to obtain information by accessing a separate information server located on a terrestrial network can be reduced, and an access time can be reduced by obtaining information necessary for a handover through a local communication between the layers in the identical ship station. In addition, an unnecessary communication procedure between a terrestrial station and the ship station can be minimized by performing, by a newly detected network, a process for a handover only when a priority is higher than that of a network link currently being used in accordance to a link priority. Rapid information through local communication in a node, not the information acquisition through communication between terrestrial networks, can be obtained by maintaining and managing information necessary for a handover by an information server ship station.

Description

TECHNICAL FIELD [0001] The present invention relates to a vertical handover system for maritime multi-band networks, and a vertical handover system for maritime multi-

The present invention relates to a vertical handover system and method for a maritime multi-band network, and proposes a logical structure and a reference communication model for vertical handover applicable to a marine multi-band network, And more particularly, to a system and method for a vertical handover for a maritime multi-band network in which a system can support seamless communication in heterogeneous handover.

Recently, the demand for various types of marine communication services has increased in addition to the message communication related to safety and security, and the demand for communication services (web browsing, e-mail, video) based on the Internet connection.

In order to support such maritime communication services, real-time data transmission, communication reliability, and high bandwidth are required, and Internet communication without interruption is required.

Satellite communication can meet these requirements, but expensive communication costs are burdensome for users. The Very High Frequency (VHF) and High Frequency (HF) networks, which have a lower communication cost than satellites, are the maritime communication standard frequency band defined by the World Radio Conference (WRC), but support communication services at a low transmission rate. On the other hand, WiMAX (Worldwide Interoperability for Microwave Access) has a high transmission rate, but its communication range is very limited compared to VHF / HF networks.

As such, the wireless communication network provides a frequency band, a transmission rate, and a communication range according to characteristics, and thus it has been difficult to efficiently provide the marine communication service at a low price by using a communication system of a single radio frequency band.

In order to cope with such maritime communication situations, a multi-band communication system in which a plurality of available wireless networks (WiMAX, VHF, HF, satellite) are integrated is considered. In a multi-band communication system, different networks operate independently, The multi-band selector selects the most suitable network considering the communication cost according to the multimedia service required and switches the selected network.

At this time, a technique for selecting and switching a wireless network between heterogeneous networks without disconnecting the user's communication is referred to as vertical handover or handoff.

IEEE 802.21 standard technology is a technology for vertical handover. IEEE 802.21 defines a Media Independent Handover (MIH) framework, a vertical handover procedure, and related commands to support seamless communication between 3GPP, 3Gpp2, and IEEE 802 family networks.

However, it has not been possible to apply the IEEE 802.21 standard, which was established as a standard for the terrestrial network, to the marine multi-band network, and the marine multi-band network consists of WiMAX, VHF, HF and satellite networks. Is not a network considered in the IEEE 802.21 standard.

In addition, in order to comply with the IEEE 802.21 standard, a media independent handover function (MIHF) for vertical handover must be installed in VHF, HF, and satellite networks.

Therefore, there has been a need to newly define an MIH framework, a vertical handover procedure, and related commands for vertical handover for marine multi-band networks.

On the other hand, the patent document of the prior art document receives from the maritime broadcast base station the maritime arrangement information including the setting information of the coastal base stations and the setting information of the maritime broadcasting stations, and sets the wireless link And a wireless link is established through a neighboring ship station where a wireless link configurable coast station is not present and a wireless link is settable. If there is no adjacent wireless link establishable coast station and a wireless link establishable adjacent ship station does not exist, INMARSAT Maritime Satellite) or MVSAT (Maritime Very Small Aperture Terminal).

[Patent Literature] Korean Patent Laid-Open No. 10-2013-0074901 (published on May 3, 2015)

Disclosure of Invention Technical Problem [8] The present invention has been made in order to solve the problems of the conventional art as described above, and it is an object of the present invention to provide a multi- And to provide a vertical handover system for a maritime multi-band network capable of defining a communication model, a vertical handover procedure, and related commands.

Another object of the present invention is to provide a vertical handover method of a handover system for a maritime multi-band network.

The problem to be solved by the present invention is not limited to the above-mentioned problem (s), and another problem (s) not mentioned can be clearly understood by a person skilled in the art from the following description.

In order to solve the above problems, a vertical handover system for a maritime multi-band network according to a preferred embodiment of the present invention is characterized in that link detection (Link_detected.indication) is performed in a VHF link layer of a medium independent handover mobile node (MIH MN) A medium independent handover function for receiving a message and informing an MIH user of a new link detection, requesting routing information of the detected VHF link, and switching a link to a VHF upon request of the MIH user (420); A link priority manager 422 for comparing the detected VHF link with the priority of the currently used HF link and managing the link priority of the available network according to the received application requirement information; And receives the application requirement information from the MIH user (MIH user), requests the link priority manager 422 for the priority of the detected link, And an information server ship station 421 for requesting the routing information of the VHF link to identify the media independent handover mobile node (MIH MN).

In order to solve the above problems, a vertical handover method for a maritime multi-band network according to a preferred embodiment of the present invention includes the steps of: (a) receiving a beacon message from a media independent handover mobile node (MIH) Informs the VHF link detection, and the MIH user transmits application requirement information to the information server ship station 421, and requests the link priority manager 422 for the priority of the detected link A handover initialization step; (b) The link priority manager 422 compares the detected VHF link with the priority of the currently used HF link, and the media independent handover function unit 420 compares the detected routing information of the VHF link with the information Server ship station 421. The information server ship station 421 identifies the MIH MNH by informing the media independent handover function unit 420 of whether MIH routing response is obtained , A serving point of contact (PoA) informs a candidate PoA and a media independent handover mobile node (MIH MN) that the media independent handover mobile node (MIH MN) A handover preparation step of informing that the over function 420 notifies the MIH user of preparation for link switching; (c) When the MIH user requests the media independent handover function unit 420 to switch to the VHF, the media independent handover function unit 420 switches the link to the VHF and the MIH user A handover execution step of informing the MIH user that the link has been switched; And (d) when the MIH user requests the media independent handover function unit 420 to complete a handover operation, the media independent handover function unit 420 transmits the candidate PoA, Informs that the link switched VHF is a new serving point of service (PoA), releases the resources allocated to the HF link and informs the media independent handover mobile node And a handover completion step of informing the MIH user and the MIH user.

The details of other embodiments are included in the detailed description and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and / or features of the present invention and the manner of achieving them will be apparent from and elucidated with reference to the embodiments described hereinafter in conjunction with the accompanying drawings. It should be understood, however, that the invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. And is provided to fully explain the scope of the present invention to those skilled in the art.

According to the present invention, it is possible to reduce the time required for the ship station to acquire information by accessing a separate information server located on the land network, acquire information necessary for handover through local communication between layers in the same ship station, Time can be reduced.

In addition, unnecessary communication procedures between the land station and the ship station for handover can be minimized by performing a handover process only when the newly detected network has a higher priority than the currently used network link according to the priority of the link , Information necessary for handover is maintained and managed in the information server ship station, so that it is possible to acquire information promptly through local communication in the node rather than acquiring information through inter-network communication.

1 is a block diagram of a marine multi-band network according to a vertical handover system and method for a marine multi-band network of the present invention.
2 is a block diagram of an IEEE 802.21 media independent handover (MIH) according to a vertical handover system and method for a maritime multi-band network of the present invention.
3 is a block diagram of a media independent handover structure according to a vertical handover system and method for a maritime multi-band network of the present invention.
4 is a configuration diagram of a media independent handover communication model for a marine multi-band network according to the present invention.
5 is a table of primitives to which a media independent handover is added for a maritime multi-band network in accordance with the present invention.
6 is a table for a primitive in which a media independent handover is omitted for a maritime multi-band network according to the present invention.
7 is a flowchart illustrating an operation of a vertical handover method for a maritime multi-band network according to the present invention.

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

Marine multi-band network

1 is a block diagram of a marine multi-band network according to a vertical handover system and method for a marine multi-band network of the present invention.

The operation of the marine multi-band network according to the vertical handover system and method for the maritime multi-band network of the present invention will be described with reference to FIG.

As shown in FIG. 1, the marine multi-band network is composed of a plurality of ship stations and WiMAX, VHF, HF, and satellite wireless network land stations. The ship station can select and communicate the most optimal network according to user requirements and environment by using multi-band communication system.

In maritime multi-band networks, there are two types of wireless communications: ship stations and ship-to-shore communications and ship-to-ship communications.

Communication between the ship station and the land station involves communication between the ship station and the WiMAX / VHF / HF / satellite network terrestrial stations in such a manner that the ship station and the land station directly communicate.

These land stations are connected to the land backbone network to provide various multimedia services to ship stations. When the ship station is located in the near future (within a few kilometers), communication with the land station of the WiMAX network ensures a fast transmission speed. Vessel station and VHF network The communication between the stations is mainly used for identifying the position of the vessel or identification of the vessel through AIS (Automatic Identification System).

HF network Communication with the land station supports low-rate communication using the PACTOR protocol, which is standard for HF band digital services. In communication between the ship station and the satellite network, satellites provide reliable communication with high data rates without being restricted by the communication distance at an expensive communication cost. Therefore, satellite network is used in case of urgent situation of ship station or high quality communication service.

Ship-to-ship communication can freely communicate between ship stations and can form an ad-hoc network. As shown in FIG. 1, when the ship station using the VHF band can not communicate with the land station directly, it can communicate with the land station using the neighboring ship station.

If a neighboring ship station is not found in the VHF band, the ship station selects an available network other than the VHF through the multi-band communication system and communicates between the ship station and the land station. At this time, the available network may be the HF network and the satellite network, and the ship station selects the most optimal network and communicates with the selected network through the vertical handover.

IEEE 802.21 media independent handover (MIH)

2 is a block diagram of an IEEE 802.21 media independent handover (MIH) according to a vertical handover system and method for a maritime multi-band network of the present invention.

The operation of the IEEE 802.21 medium independent handover (MIH) according to the vertical handover system and method for a maritime multi-band network of the present invention will now be described with reference to FIGS. 1 and 2. FIG.

The IEEE 802.21 working group (WG) has established a basic standard for frameworks and mechanisms in 2008 to support seamless handover between heterogeneous networks and continues to work on the development of a detailed working group of related technologies .

IEEE 802.21 MIH technology provides link layer information and related network information to an upper layer regardless of a specific node or network to facilitate handover.

As shown in FIG. 2, a media independent handover function (MIHF) 200, which is a logical entity, is located between the link and the upper layer 300 and instructs the MIH user And provides three main communication services.

First, the Media Independent Event Service (MIES) detects the change of the lower layer 100 of the communication layer 2 or lower and provides the related event information to the upper layer. The related event information is the dynamic information of the link (signal strength, data rate of the link), the link status (whether or not the link is connected), and the expected link event.

Second, the Media Independent Command Service (MICS) is a command service for the MIH user to control the state of the link layer related to the handover.

Third, Media Independent Information Service (MIIS) is a service that provides related information when inquiring about the resources and functions of networks located in a specific area.

Maritime multi-band network media independent handover structure

3 is a block diagram of a media independent handover structure according to a vertical handover system and method for a maritime multi-band network of the present invention.

The operation of the marine multi-band network independent handover structure according to the vertical handover system and method for the maritime multi-band network of the present invention will be described with reference to FIGS. 1 to 3 as follows.

The MIH for the ship station is based on the IEEE 802.21 MIH structure and consists of WiMAX (500), VHF (600), HF / MF (700), and Satellite (800) networks in the lower physical layer and data link layer. Use the network as the default communication mode.

A medium independent handover function unit 420 exists between the network layer 410 and the data link layer and transmits different network technologies of a lower layer to an upper layer to select and communicate an optimal network according to a network selection criterion .

Unlike the IEEE 802.21, an information server ship (IS ship) 421 and a link priority manager (LPM) 422 module function are added to the media standalone handover function unit 420 for a ship station .

The information server ship station 421 maintains and manages information related to handover in the media independent handover function unit 420. This information server ship station 421 is a separate information server (IS) In order to reduce the time required for obtaining information.

In the case of a VHF link in the sea, communication is performed in a time division multiple access (TDMA) system composed of 2250 slots in one minute, so that information necessary for handover can be transmitted to the information server It may take minutes.

In order to overcome this disadvantage, the present invention adds a module of the information server ship station 421 in the media independent handover function unit 420 of the ship station to acquire information necessary for handover through local communication between layers in the same ship station So that the time required for connection can be reduced.

The link priority manager 422 sets the link priority of the available network according to the application requirement received from the information server ship station 421. [

The newly detected network performs a handover procedure only when the priority of the network link is higher than that of the currently used network link according to the priority of the link so as to minimize unnecessary communication procedures between the land station and the ship station for handover .

As shown in Fig. 3, in case of WiMAX network, a media independent handover function is implemented according to the IEEE 802.21 standard applied to the terrestrial network, and a procedure for handover is performed.

On the other hand, in the case of VHF, HF / MF, and satellite networks, there is no medium independent handover function, and only the ship station is equipped with a media independent handover function.

Media independent handover communication model

4 is a configuration diagram of a media independent handover communication model for a marine multi-band network according to the present invention.

The operation of the medium independent handover communication model for the maritime multi-band network according to the present invention will be described with reference to FIGS. 1 to 4 as follows.

A media independent handover communication model for a maritime multi-band network according to the present invention includes the concept of a ship ad hoc network.

The MIH point of service (MIH PoS) is a network entity that exchanges media independent handover messages between mobile nodes, and is a core network of WiMAX in a maritime multi-band network.

The MIH point of attachment (MIH PoA) is a two-tier link endpoint for exchanging media independent handover messages with ship stations.

The Non-MIH PoA is a two-tier link endpoint between the ship station and the network without media independent handover capability.

A media independent handover (MIH) mobile node (MIH MN) is a mobile node (ship station) capable of communication between all layers of a multi-band multi-band and two layers.

 A VHF relay node (VHF RN) is a node where a ship station using VHF communication requests data delivery to a neighboring ship station for communication with a land station. This is an entity to support inter-ship VHF ad hoc networks in maritime multi-band networks.

 Interrupt PoA is a two-tier link end point between the ship station and the switched network immediately upon link forwarding without urgent message forwarding, without preparing the ship station for handover.

The reference points for the handover communication of these network entities are as follows.

 R1 (MIH MN ⇔ serving non-MIH PoA) is a communication point between the medium independent handover mobile node and the non-MIH PoA. In this case, the medium independent handover mobile node transmits the network information of the currently used link to the information server ship station 421).

 R2 (MIH MN ⇔ candidate non-MIH PoA) is a communication point between a medium independent handover mobile node and a non-MIH PoA that is likely to switch networks. In this way, the link end point where the ship station is likely to switch to a network is called a candidate point of contact (PoA), and when the ship station detects a link different from the currently used link, the communication between the two layers is equivalent.

 R3 (MIH MN ⇔ interrupt non-MIH PoA) is the communication point between the media independent handover mobile node and the Interrupt PoA. In an urgent message delivery or emergency situation, the network is selected and communicated to the interrupt PoA immediately without a preparation procedure for handover in the currently used link. An example is two-tier communication between a ship station and a satellite network in a maritime multi-band network.

 R4 (MIH MN ⇔ VHF RN) is the communication point between the medium independent handover mobile node and the VHF RN ship station. When a VHF link for data delivery is detected, the media independent handover mobile node stores the routing information of the VHF RN in the information server ship station 421 in the media independent handover function unit 420 and uses the information for handover to the VHF network . This is for carrying out the handover using the information stored in the information server ship station 421 without separately considering the route creation procedure for the VHF handover.

R5 (MIH MN ⇔ candidate MIH PoA) is the communication point between the medium independent handover mobile node and the MIH PoA that is likely to switch networks. In a maritime multi-band network, this corresponds to a two-layer communication between a ship station and a WiMAX network that is likely to be handed over. In this case, the handover procedure conforms to the IEEE 802.21 standard.

 Vertical media independent handover procedure

5 is a table of primitives to which a media independent handover is added for a maritime multi-band network in accordance with the present invention.

6 is a table for a primitive in which a media independent handover is omitted for a maritime multi-band network according to the present invention.

7 is a flowchart illustrating an operation of a vertical handover method for a maritime multi-band network according to the present invention.

The operation of the vertical handover method for a maritime multi-band network according to the present invention will now be described with reference to FIGS. 1 to 7. FIG.

 Upon receipt of the beacon message at the VHF link layer of the medium independent handover mobile node, a Link_detected.indication event is generated and transmitted to the media independent handover function unit 420. This is defined in IEEE 802.21, and when a new VHF link is detected, it notifies the media independent handover function unit 420 of an event at the corresponding link layer (S101).

 5, the event of the step S100 notifies the MIH user of the new link detection through the medium independent handover function unit 420 through the MIH_link_detected.indication message (S102).

 5, the MIH user receiving the message MIH_link detection acknowledgment message transmits the application requirement information to the information server ship station 421 through the message MIH_Application.requirement message (S103).

The application requirement information includes status information such as a quality of service (QoS) requirement, a location and a moving speed of the mobile node, and the like. This information is maintained in the information server ship station 421, This is to acquire information quickly through local communication within the node, not through information acquisition through inter-network communication on the land.

 The information server ship station 421 transmits a link priority request (Link_priority.request) message including the message MIH_application requirement information and available link information to the link priority manager 422 in FIG. 5 received from the application layer, (S104).

At this time, if the detected link has a low priority, the process for handover does not proceed, and the detected link event is ignored. This is to minimize the unnecessary handover process by prioritizing the link.

The link priority manager 422 compares the VHF, which is the link detected based on the link priority request message information (Link_priority.request) message information, with the HF link priority currently being used (S105). In general, in maritime multi-band communication, the priority of the link is WiMAX, HF, VHF, and satellite network. Since the VHF link has a high priority, the handover preparation process of the VHF link is requested through a link priority request (Link_HO_preparation.request) message.

 In the case of the VHF link, the media independent handover function unit 420 considers routing information of the detected link message to the information server ship station (MIH_Get_routing.request) 421 (S106).

 The information server ship station 421 identifies whether the medium independent handover mobile node (MIH MN) is a destination node or a forwarding node and transmits the MIH_Get_routing.reponse message to the media independent handover function unit 420 (S107).

 If the medium independent handover mobile node is a forwarding node, it receives a message delivery request from the VHF RN and waits for the next handover process until the routing information is secured in the information server ship station 421. This is because it may take a long time (several minutes) to generate a path in ad hoc communication between ship stations.

 If the media independent handover mobile node is the destination node, the media independent handover function 420 determines whether the MIH_MODE_HANDOVER_MODE The handover target link is notified to the serving contact point through an MIH_MN_HO_commit.request message (S108).

 The serving point of contact informs the candidate point of contact that the medium independent handover mobile node will soon be handed over to the target link through the MIH Handover Commit message of FIG. 5 (S109) Response message (MIH_MN_HO_commit.response) message to the serving contact point (S110).

 The serving point forwards the MIH_MN_HO_commit.response message to the media independent handover mobile node in response to the MIH_MN_HO_commit.request message ( S111).

 The media independent handover function unit 420 notifies the MIH user that the preparation for link switching is completed through the message MIH_MN_HO_commit.confirm (S112).

 The MIH user requests the medium independent handover function unit 420 to switch to the VHF in the MIH_Link_action.request message (S113).

 The media independent handover function unit 420 switches the link to the VHF and informs the MIH user that the link has been switched through the MIH_link_up.indication (S114).

When the link switching is completed, the MIH user requests the media independent handover function unit 420 to complete the handover operation through the MIH_HO_complete.request message (S115).

The media independent handover function unit 420 transmits an MIH_HO_complete.request message to the candidate contact point to notify that the link switched network VHF is a new serving contact point at step S116.

The switched network informs that the handover is completed to the existing serving point through the internal handover finalization message, and the resources allocated to the HF network are released (S117).

 The new serving contact point notifies the medium independent handover mobile node through the MIH_HO_complete.reponse message that the handover has been successfully performed (S118), and the media independent handover function unit And finally notifies the MIH user of the completion of the MIH handover through the MIH_HANDOVER_Complete confirmation message (MIH_HO_complete.confirm) (S119).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It will be understood by those skilled in the art that various changes, modifications, substitutions, and equivalents may be made therein without departing from the spirit and scope of the invention.

Claims (9)

Upon receipt of a Link_detected.indication message from the VHF link layer of the MIH MN, the MIH user informs the MIH user of the new link and requests the routing information of the detected VHF link A media independent handover function unit 420 for switching a link to the VHF according to the request of the MIH user (MIH user);
A link priority manager 422 for comparing the detected VHF link with the priority of the currently used HF link and managing the link priority of the available network according to the received application requirement information; And
Receives the application requirement information from the MIH user (MIH user), requests the link priority manager 422 for the priority of the detected link, and the media independent handover function unit An information server ship station (421) for requesting routing information of a VHF link to identify the media independent handover mobile node (MIH MN);
≪ RTI ID = 0.0 >
Vertical handover system for marine multi - band networks.
The method according to claim 1,
The information server ship station 421
If the medium independent handover mobile node (MIH MN) is a destination node or a destination node, the media independent handover function unit 420 determines whether a serving PoA is transmitted to the HF link before the VHF link is switched The handover target link is notified,
And the next handover process is suspended until the routing information is secured if the medium independent handover mobile node (MIH MN) is a forwarding node
Vertical handover system for marine multi - band networks.
(a) When a medium independent handover mobile node (MIH MN) receives a beacon message, the MIH user informs the MIH user of VHF link detection, and the MIH user transmits application requirement information to the information server ship station 421 And for requesting the link priority manager 422 to request the priority of the detected link;
(b) The link priority manager 422 compares the detected VHF link with the priority of the currently used HF link, and the media independent handover function unit 420 compares the detected routing information of the VHF link with the information Server ship station 421. The information server ship station 421 identifies the MIH MNH by informing the media independent handover function unit 420 of whether MIH routing response is obtained , A serving point of contact (PoA) informs a candidate PoA and a media independent handover mobile node (MIH MN) that the media independent handover mobile node (MIH MN) A handover preparation step of informing that the over function 420 notifies the MIH user of preparation for link switching;
(c) When the MIH user requests the media independent handover function unit 420 to switch to the VHF, the media independent handover function unit 420 switches the link to the VHF and the MIH user A handover execution step of informing the MIH user that the link has been switched; And
(d) When the MIH user requests the media independent handover function unit 420 to complete the handover operation, the media independent handover function unit 420 transmits the candidate PoA Informs that the link switched VHF becomes a new serving point of service (PoA), releases resources allocated to the HF link, and determines whether handover to the new serving point of service (serving PoA) MN) and the MIH user (MIH user);
≪ / RTI >
A Vertical Handover Method for a Marine Multi - Band Network.
The method of claim 3,
The step (a)
Upon receipt of the beacon message at the VHF link layer of the media independent handover mobile node (MIH MN), a Link_detected.indication message is generated and transmitted to the media independent handover function unit 420. [
The media independent handover function 420 notifies the MIH user of a new link detection through an MIH_link_detected.indication message;
The MIH user transmits the application requirement information to the information server ship station 421 through an MIH_application.requirement message; And
The information server ship station 421 transmits a link priority request message including the MIH_application.requirement information and available link information to the link priority manager 422, Requesting a priority of the sensed link;
≪ / RTI >
A Vertical Handover Method for a Marine Multi - Band Network.
The method of claim 3,
The step (b)
(b-1) the link priority manager 422 comparing the priorities based on a link priority request message (Link_priority.request) message;
(b-2) If the priority is the VHF link, the media independent handover function 420 transmits the routing information of the link message sensed using interchannel ad hoc communication to MIH_Get_routing.request ) To the information server ship station (421) through a message; And
(b-3) The information server ship station 421 identifies whether the medium independent handover mobile node (MIH MN) is a destination node or a forwarding node and transmits the MIH message through an MIH_Get_routing.reponse message Informing the handover function unit 420;
Wherein the handover method comprises the steps of:
6. The method of claim 5,
The step (b-3)
When the medium independent handover mobile node (MIH MN) is the destination node, the media independent handover function unit 420 transmits the VHF link, which is the candidate point PoA, on the HF link serving as the serving PoA, Notifying the handover target link to the serving PoA through the MIH_MN_HO_commit.request message before the switching; And
If the MIH MN is the forwarding node, suspending the next handover process until the routing information is secured in the information server ship station 421;
Wherein the handover method comprises the steps of:
The method of claim 3,
The step (c)
Requesting the MIH user (MIH user) via the MIH_Link_action.request message to switch to the VHF to the media independent handover function unit 420; And
The media independent handover function unit 420 switches the link to the VHF and notifies the MIH user that the link has been switched through an MIH_link_up.indication message (MIH_Link_up.indication);
≪ / RTI >
A Vertical Handover Method for a Marine Multi - Band Network.
The method of claim 3,
The step (d)
Upon completion of the link switching, the MIH user requests the media independent handover function unit 420 to complete the handover operation through an MIH_HO_complete.request message ;
The media independent handover function 420 delivers the MIH_HO_complete.request message to the candidate PoA to determine whether the link switched VHF link has a new serving point of interest ;
Informing the link switched network that the handover is completed to an existing serving point via an internal handover finalization message and releasing resources allocated to the HF link;
Informing the medium independent handover mobile node (MIH MN) through the MIH_HO_complete.reponse message whether the handover has been made to the new serving point of service; And
The media independent handover function 420 notifies the MIH user of MIH handover completion through an MIH_HO_complete.confirm message;
≪ / RTI >
A Vertical Handover Method for a Marine Multi - Band Network.
The method of claim 3,
The application requirement information
Wherein the mobile node includes at least one of a communication service quality requirement, a location of a mobile node, and a movement speed of the mobile node.

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