KR101064428B1 - Asynchronous Mobile Communication System and Handover Method in Thereof - Google Patents

Abstract

An asynchronous mobile communication system and a handover method thereof capable of guaranteeing service continuity by switching a handover method to a hard handover when a radio resource of a target base station is insufficient during a soft handover in an asynchronous mobile communication system.

In the handover method according to the present invention, the mobile communication terminal requests a soft handover to an asynchronous mobile communication system, and the asynchronous mobile communication system requests to perform a hard handover to the mobile communication terminal when the soft handover fails. Receiving a result of measuring radio resources between neighboring cells having different call frequencies from the second process and the mobile communication terminal, and referring to the radio resource measurement results between neighbor cells measured by the mobile communication terminal by the asynchronous mobile communication system; And performing a hard handover to an adjacent cell having a different call frequency.

According to the present invention, it is possible to prevent the failure of the call during handover and provide continuous service.

Asynchronous mobile communication system, handover

Description

Asynchronous Mobile Communication System and Handover Method in Thereof}

1 is a structural diagram of an asynchronous mobile communication system,

2 is a diagram for explaining a handover concept in an asynchronous mobile communication system;

3 is a flowchart illustrating a handover method in an asynchronous mobile communication system according to the present invention;

4 is a view for explaining a compression mode applied to the handover method according to the present invention;

5 is a flowchart illustrating a general handover method in an asynchronous mobile communication system.

Description of the Related Art [0002]

100: mobile communication terminal 200: wireless access network

300: core network 210, 220: wireless network subsystem

212, 214, 222, 224: Node B 216, 226: Wireless network controller

310: exchanger 320: gateway exchanger

330: SGSN 340: GGSN

The present invention relates to a handover in a mobile communication system, and more particularly, in the case of a soft handover in an asynchronous mobile communication system, when the radio resources of the target base station are insufficient, the handover scheme is switched to a hard handover to guarantee service continuity. An asynchronous mobile communication system capable of doing this, and a handover method thereof.

Asynchronous mobile communication system represented by Wideband Code Division Multiple Access (WCDMA) is a representative third generation mobile communication technology that provides high capacity and high data rate for voice and data. The asynchronous mobile communication system supports high-speed mobility, excellent service quality, and high data transfer performance. Therefore, the asynchronous mobile communication system coexists with the second generation (2.5 generation) mobile communication network. It is expected to be integrated.

Like the synchronous mobile communication system, the asynchronous mobile communication system must support handover between base stations to ensure subscriber mobility.

Soft handover does not change the talk frequency when the mobile communication terminal is at the boundary between cells, i.e., away from the home base station (currently connected base station, node B in an asynchronous mobile communication system) and enters the coverage of the adjacent base station. When the signal strength of the home base station decreases below the reference value while simultaneously transmitting and receiving a signal simultaneously with the base station and the neighboring base station using the same frequency, it means that the connection with the base station is maintained and the call can be maintained through the neighboring base station.

By using such a handover in a mobile communication system, it is possible to maintain a low call loss rate and call quality. A general soft handover method in an asynchronous mobile communication system will be described with reference to FIG.

5 is a flowchart illustrating a general handover method in an asynchronous mobile communication system. In the figure, the SRNC represents a wireless network controller to which Node B, which is currently connected and receives services, is represented by an SRNC, and the DRNC to which a Node B to which a mobile communication terminal is to be handed over is connected.

In the state where the mobile communication terminal is located at the boundary area between the SRNC and the DRNC and establishes a radio link with a specific cell of a specific node B connected to the SRNC, the mobile communication terminal is in a radio resource state with the currently connected node B and the neighboring node B. Is periodically measured and reported to the SRNC (S201). The SRNC determines the handover target RNC when the radio resource measurement value with the Node B to which the mobile communication terminal is currently connected is lower than or equal to the reference value by referring to the radio resource measurement value received from the mobile communication terminal (DRNC). Request Over That is, the DRNC requests the mobile communication terminal to establish a radio link with the Node B to be handed over (S203).

Accordingly, the DRNC responds to the radio link establishment request of the SRNC (S205), and establishes a radio link with the Node B (S207). In addition, the DRNC establishes a data transmission bearer with the Node B to be handed over by the mobile communication terminal (S209), and thus a protocol for establishing a link of the transport layer (Access Link Control Application Part; ALCAP) is set.                         

Thereafter, the DRNC reports that the radio link establishment is completed to the SRNC (S211), and a data transmission bearer is established between the DRNC and the SRNC (S213).

Next, the SRNC transmits channel information to the mobile communication terminal to instruct handover (S215), and the Node B to which the mobile communication terminal is currently connected requests to release the radio link to the SRNC (S217). In addition, the Node B to be handed over by the mobile communication terminal requests the radio link restoration to the DRNC (S219), and the DRNC receiving the request requests the radio link restoration to the SRNC (S221).

Meanwhile, as the mobile communication terminal receiving the handover instruction message completes channel allocation with the node B to be handed over and reports to the SRNC that the handover is completed (S223), the SRNC requests the node B to delete the radio link. If the node B responds (S227), the data transmission bearer between the node B and the SRNC is released (S229).

In the soft handover in the asynchronous mobile communication system described above, when the mobile communication terminal lacks radio resources of the handover target cell of the node B to be handed over to, the handover cannot be performed and a call failure occurs. That is, in step S207 of FIG. 5, when the radio resource of the node B's soft handover target cell is insufficient, handover fails, and thus there is a problem that continuous service cannot be provided to the mobile communication terminal.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and when a soft handover in an asynchronous mobile communication system lacks radio resources of a cell to be handed over, by switching the handover method to hard handover, the call of the mobile communication terminal is performed. There is a technical problem to provide an asynchronous mobile communication system and a handover method thereof that can prevent the failure.

According to an aspect of the present invention, there is provided a handover method comprising: a first process of requesting a soft handover from a mobile communication terminal to an asynchronous mobile communication system; A second step of the asynchronous mobile communication system requesting hard handover to the mobile communication terminal when the soft handover fails; And receiving a result of measuring radio resources between adjacent cells having different talk frequencies from the mobile communication terminal, and having a different talk frequency by referring to a result of measuring radio resources between adjacent cells measured by the mobile communication terminal by the asynchronous mobile communication system. And a third process of performing hard handover to an adjacent cell. In addition, the asynchronous mobile communication system according to the present invention for achieving the above technical problem, Node B for supporting the wireless section communication of the mobile communication terminal under the control of the radio network controller; And requesting to operate the compression mode to the mobile communication terminal when the soft handover fails according to the soft handover request of the mobile communication terminal, and the radio resource measurement result between adjacent cells having different call frequencies measured by the mobile communication terminal. It includes a; wireless network controller for performing a hard handover to a neighbor cell with a different talk frequency with reference to.

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

1 is a structural diagram of an asynchronous mobile communication system.

As shown, the asynchronous mobile communication system is a voice and / or voice to the mobile communication terminal 100 through the wireless access network 200, the wireless access network 200 for supporting and controlling the wireless section connection with the mobile communication terminal 100 It consists of a core network 300 to provide data services.

More specifically, the wireless access network 200 is composed of a plurality of wireless network subsystems (RNS; 210, 220), each wireless network subsystem (210, 220) is a wireless section communication of the mobile communication terminal 100 Node B (212, 214, 222, 224) as an access point for supporting the, and a radio network controller (RNC, 216, 226) for managing radio resources for managing and controlling a plurality of Node B.

The services provided by the mobile communication system to the mobile communication terminal are largely divided into circuit switched service and packet switched service. For example, voice telephone service is included in circuit switched service, and browsing service through Internet access is included in packet switched service. do. In case of supporting circuit switching service, the wireless network controller 216, 226 is connected to the switchboard (MSC, 310) of the core network 300, and the switchboard 310 is connected to the gateway exchange 320 for communication with the external network. do. The gateway exchange 320 is responsible for managing the connection with other networks.

Meanwhile, the packet switching service is provided by a Serving GPRS Support Node (SGSN) 330 and a Gateway GPRS Support Node (GGSN 340) of the core network 300. The SGSN 330 supports packet communication to a wireless network controller. The GGSN 340 manages connections to other packet switched networks, such as the Internet.

In such an asynchronous mobile communication system, the radio network switch in charge of Node B direct management is called a control radio network controller (CRNC), which is responsible for the management of common radio resources. In addition, a radio network controller managing a dedicated radio resource allocated to each mobile communication terminal is called a serving radio network controller (SRNC). The CRNC and the SRNC may be the same, but the CRNC and the SRNC may be different when the mobile communication terminal moves out of the SRNC to the area of another radio network controller.

FIG. 2 is a diagram illustrating a concept of handover in an asynchronous mobile communication system. In FIG. 2, the CRNC and the SRNC are the same, and the target wireless network controller to be handed over by the mobile communication terminal is represented by a drift RNC.                     

In FIG. 2, the mobile communication terminal 100 establishes a radio link with four cells. That is, the node B (cell 2 and cell 3 of the node B 214 and the node B (connected to the DRNC 220) connected to the cell 3 of the node B 212 connected to the SRNC 210 to use the service. Since the radio link is established with the cell 1 of 222, it can be seen that the mobile communication terminal 100 exists in the handover area.

In this case, the SRNC periodically receives the radio resource measurement value from the mobile communication terminal 100 to determine whether to handover and the base station to be handed over. When the handover method is soft handover, the base station to be handed over is a node. Cell 1 of the B 222, and establishes a radio link with the Node B (222) to the DRNC 220, and should be controlled to access the mobile communication terminal 100 to provide a service.

However, when the SRNC 210 requests the DRNC 220 to establish a radio link and the DRNC 220 attempts to establish a radio link with the Node B 222, the Node B 222 to which the mobile communication terminal 100 hands over. When the radio resource of the cell 1 is insufficient, the radio link setup fails, and as a result, the handover fails. That is, in the asynchronous mobile communication system, the soft handover is for the mobile communication terminal 100 to change only the access cell without changing the communication frequency, and the mobile communication terminal is handed to the same cell as the cell with which the mobile communication terminal is currently receiving the service. If an attempt is made to over, when the radio resource of the corresponding cell becomes insufficient, handover is not performed and the service is dropped.

In order to solve this problem, the present invention converts the handover method to hard handover when there is insufficient radio resource of a target cell for performing soft handover, and searches for a talk frequency having excellent radio section characteristics in the same Node B. By handing over to the cell using the corresponding frequency, the continuity of the mobile communication service can be guaranteed.

That is, in FIG. 2, when the radio resource of the cell 1 of the Node B 222 is insufficient, the mobile communication terminal 100 measures the radio resource of another cell, and has a good radio resource measurement result (for example, cell 2). Hard handover, a process of requesting a soft handover to the asynchronous mobile communication system, a process of requesting to perform a hard handover to the mobile communication terminal when the soft handover fails As the communication terminal measures radio resources between neighboring cells having different call frequencies, the asynchronous mobile communication system performs a hard handover with reference to the radio resource measurement result between neighbor cells measured by the mobile communication terminal.

3 is a flowchart illustrating a handover method in an asynchronous mobile communication system according to the present invention.

With the mobile communication terminal located at the boundary between the SRNC and the DRNC and establishing a radio link with the specific cell of the specific node B connected to the SRNC, the mobile communication terminal is the node B currently connected to the adjacent node B with the same talk frequency. The radio resource (channel code, power consumption, received power level, etc.) state of the device is periodically measured and reported to the SRNC (S101). The SRNC determines the handover target RNC (DRNC) when the radio resource measurement value with the Node B to which the mobile communication terminal is currently connected is lower than the reference value by referring to the radio resource measurement value received from the mobile communication terminal. Request Over That is, the DRNC requests the mobile communication terminal to establish a radio link with the Node B to be handed over (S103).

Accordingly, the DRNC responds to the SRNC's request for establishing a radio link (S105), and attempts to establish a radio link with the node B. In this case, when the radio resource of the node B's handover target cell is insufficient, the DRNC radio link with the node B. The setting fails (S107), the DRNC reports it to the SRNC (S109).

The SRNC, which has been reported that the radio link setting has failed, instructs the mobile communication terminal 100 to drive the compressed mode, and requests to search for another communication frequency having excellent radio section characteristics (S111). In other words, the handover method is changed to hard handover.

Accordingly, the mobile communication terminal measures radio resources for each talk frequency assigned to each cell of the handover target Node B, and reports them to the SRNC (S113). Based on this, the SRNC selects an optimal handover cell and requests the DRNC to establish a radio link with the corresponding cell (S115).

The DRNC responds to the SRNC's radio link establishment request, establishes a radio link with the node B to which the cell belongs (S117), reports that the radio link establishment is completed (S119), and then the resource and the node between the SRNC and the node B. The bearer is set (S121).

Next, the SRNC transmits channel information to the mobile communication terminal to instruct a handover (S123). As the mobile communication terminal reports that channel allocation is completed to the SRNC, the handover is completed (S125). The connection with the Node B connected with the mobile communication terminal is released (S127). When the handover is completed as described above, the SRNC requests the mobile communication terminal to release the compression mode (S129).

The handover method described above has proposed a method for improving the handover success rate by switching to a hard handover in which handover to a cell having a different talk frequency when a soft handover fails. Here, hard handover is enabled by the compression mode function of the mobile communication terminal.

In order to search for neighboring cells having different frequencies during a call for handover between frequencies, two receiving high frequency paths are generally required in the mobile communication terminal. However, since it is very impractical to implement two high frequency receiver circuits in one mobile communication terminal, the mobile terminal having one high frequency receiver circuit temporarily stops transmitting and receiving operations during a call to search for adjacent cells of different frequencies. The function is called the compression mode.

In an asynchronous mobile communication system, one frame has a length of 10 msec and consists of 15 slots. When the mobile communication terminal operates in the compression mode, data transmission and reception is performed by increasing the reception power in a part of one frame period, and during the rest of the time, data transmission and reception are stopped and the reception frequency of the mobile communication terminal is temporarily set to the adjacent cell frequency. In this case, the handover with the neighbor cell and the radio resource characteristics are searched.

FIG. 4 is a diagram for explaining a compression mode applied to the handover method according to the present invention and shows a case in which the compression mode is performed over two frames.                     

As shown, a normal frame has a length of 10 msec, and when the mode is converted to a compression mode and transmits a compressed frame, data transmission and reception are not allowed during the period TGL. Instead, the transmission error in the slot region TGL in the compressed frame is higher than the power in the normal frame, thereby maintaining the same frame error probability as in the normal frame.

The mobile communication terminal searches for signal strength for a new call frequency by cutting off the frequency of the current call setting in the section (TGL) and changing the frequency.When the section (TGL) ends, the mobile communication terminal converts the frequency back to the preset frequency to perform communication. To perform.

In this way, the compression mode allows the mobile communication terminal to temporarily change the frequency during a call to determine the handover by measuring radio section characteristics with other cells.

In the present invention, during the soft handover, when the radio resources of the handover target cell are insufficient, the mobile communication terminal is driven in a compressed mode to search for another talk frequency, and a cell having excellent radio range characteristics is selected from the other talk frequencies. In this case, hard handover is performed to the corresponding cell.

As such, those skilled in the art will appreciate that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof. Therefore, the above-described embodiments are to be understood as illustrative in all respects and not as restrictive. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

When the soft handover is performed in the asynchronous mobile communication system, the present invention described above switches the handover method to hard handover when the handover target cell runs out of radio resources, thereby preventing failure of the call during handover and continuous service. Can be provided.

In particular, by using the compression mode function to switch to hard handover, handover is possible regardless of the connection type between the mobile communication terminal and the base station to be handed over, and handover to the optimal cell measured by the mobile communication terminal is possible. As a result, the handover success rate is increased.

Claims (5)

A first step of the mobile communication terminal requesting a soft handover to an asynchronous mobile communication system; A second step of the asynchronous mobile communication system requesting hard handover to the mobile communication terminal when the soft handover fails; And Receives a result of measuring radio resources between neighboring cells having different talk frequencies from the mobile communication terminal, and the asynchronous mobile communication system refers to the radio resource measurement result between neighbor cells measured by the mobile communication terminal, and has a different talk frequency. Performing a hard handover to a cell; Handover method in an asynchronous mobile communication system comprising a. The method of claim 1, The first process is performed by a mobile communication terminal connected to a first node B to perform a service by measuring a radio resource with an adjacent cell having the same talk frequency, and then connecting the first node B to a wireless network controller (serving wireless network). Report to the controller) In the second process, the serving radio network controller selects a soft handover target radio network controller (drift radio network controller) with reference to the radio resource measurement value, and the second node B to which the mobile communication terminal performs soft handover. Requesting the drift radio network controller to establish a radio link with the drift radio network controller; When the drift radio network controller attempts to establish a radio link with the second node B, reporting a radio resource shortage to the serving radio network controller when the radio resource of the soft handover target cell is insufficient; And Requesting, by the serving radio network controller, to operate the compression mode to the mobile communication terminal. The method of claim 1, In the third process, a serving radio network controller managing a radio resource allocated to the mobile communication terminal requests the mobile communication terminal to operate a compression mode so that the mobile communication terminal communicates with an adjacent cell having a different talk frequency. Measuring and transmitting a radio resource to the serving radio network controller; Selecting, by the serving radio network controller, a cell having a good radio resource measurement value among neighboring cells having different talk frequencies and requesting to establish a radio link to a drift radio network controller to which a node B to which the cell belongs is connected; Establishing, by the drift radio network controller, a radio link with a node B to which the cell belongs, and reporting a radio link establishment result to the serving radio network controller; Establishing a radio resource and a bearer between the serving radio network controller and the Node B to which the cell belongs; The serving wireless network controller instructing a handover to the mobile communication terminal and receiving a response; Releasing a connection with the Node B to which the serving radio network controller is already connected; And Requesting, by the serving radio network controller, to release the compression mode to the mobile communication terminal; Handover method in an asynchronous mobile communication system comprising a. A node B supporting radio section communication of a mobile communication terminal under control of a radio network controller; And When the soft handover fails due to the soft handover request of the mobile communication terminal, the mobile communication terminal is requested to drive the compression mode, and the radio resource measurement result between neighboring cells having different call frequencies measured by the mobile communication terminal is calculated. A radio network controller for performing hard handover to adjacent cells having different talk frequencies with reference; Asynchronous mobile communication system comprising a. 5. The method of claim 4, The radio network controller selects a cell having an excellent radio resource measurement value from among neighbor cells having different talk frequencies based on a radio resource measurement result between neighboring cells having different talk frequencies measured by the mobile communication terminal in the compression mode. Asynchronous mobile communication system, characterized in that to perform a hard handover to the cell.

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