KR100524739B1 - Soft handover method for mobile telecommunication system - Google Patents

Abstract

The present invention relates to a soft handover method of a mobile communication system. In particular, it is possible to verify an error that may occur when measuring synchronization parameters for soft handover, thereby increasing the success rate of soft handover while minimizing the influence on the existing call. The present invention relates to a soft handover method of a mobile communication system. In the conventional soft handover method, since the controller receives a value measuring the difference between the SFN of the target base station received as the terminal enters the target base station cell area and the CFN for the frame currently received, the controller uses the same without verification. If there was an error, the soft handover would fail and affect the current call. In view of the above problems, the present invention considers the BFN of the target base station obtained through node synchronization with the base station as the SFN of the target base station, and corrects the CFN corrected with the frame offset value obtained from the measurement value received from the terminal. The method provides a soft handover method of the mobile communication system further comprising a verification step comparing the CFN of the mobile communication system to detect the measurement error of the terminal, thereby minimizing the influence on the set call. It can increase the effect.

Description

Soft handover method of mobile communication system {SOFT HANDOVER METHOD FOR MOBILE TELECOMMUNICATION SYSTEM}

The present invention relates to a soft handover method of a mobile communication system. In particular, it is possible to verify an error that may occur when measuring synchronization parameters for soft handover, thereby increasing the success rate of soft handover while minimizing the influence on the existing call. The present invention relates to a soft handover method of a mobile communication system.

As mobile communication systems are generalized and users frequently carry terminals and move between cells, the importance of soft handover between base stations is gradually increasing.

In a wideband code division multiple access (W-CDMA) system, a counter is used to synchronize a node between a control station and a base station. A Radio Network Controller (RNC) uses a counter called RFN (RNC Frame Number), and a Node B uses a counter called Node B Frame Number (BFN), all of which increase by 1 every 10 ms. The maximum value is 4095.

In addition, the base station manages a call by separately setting a counter called a cell system frame numebr (SFN) for each cell together with the BFN. The SFN is a value spaced apart from the BFN by an arbitrary time within 10 ms.

The terminal receives the SFN of the base station through the broadcast channel of the transmission channel.

The base station uses a transmission channel for transmitting and receiving a user data frame with the control station, and inserts a frame number (CFN), which is a frame number, together with the user data frame. The frame number is also increased by 1 every 10 ms. The maximum forwarding value is 255 (for common channels and designated channels except for calling channels) or 4095 (calling channel among common channels) depending on the front channel. The difference is as much as the offset. The frame offset information is also transmitted to the base station and the terminal so that the frame number (CFN) for any frame is managed in the same way to the control station, the base station, and the terminal.

In summary, the base station and the control station performs synchronization with the RFN and the BFN, and the terminal has a base station-specific SFN ( BFN), the control station manages the call by inserting CFN (SFN + frame offset) for the data frame from the base station. The frame offset is also provided to the base station and the terminal so that all members know the CFN. Thus, the ultimate counter that can distinguish the data frames for the call is the CFN generated by the control station as the subject.

Now, a case where the terminal performs soft handover in proximity to a cell of an adjacent target base station will be described.

When the terminal approaches the cell of the neighboring target base station, the target base station transmits its own SFN to the terminal. The terminal measures an offset, which is a difference between the SFN of the target base station and the CFN managed by the terminal, and transmits the offset to the control station. The control station calculates a frame offset to be transmitted through the offset and transmits the frame offset to the handover target base station.

This allows the terminal to simultaneously communicate with the currently serving base station and the target base station to be moved, and the base stations transmit the same data frame to the control station together with the CFN, and the quality of the signals of both base stations arriving at the same time at the control station. This excellent one is selected and transmitted to the upper layer.

Now, referring to FIG. 1 for a more detailed description.

FIG. 1 is a diagram illustrating a synchronization parameter for conventional soft handover. As shown in FIG. 1, various parameters DOFF are controlled from the control station 40 to the terminal 10 during an initial connection using a radio resource control (RRC) protocol. The parameters include a frame offset value and a chip offset value for a base station currently serving. Through this, the terminal 10 can know the CFN value from the SFN value received from the service base station 20 by itself.

The chip offset value means an offset with respect to specific data in the data frame.

The control station 40 transmits the sum of the frame offset value and the chip offset value to the service base station 20 by using a Node B Application Part (NBAP) protocol, so that the service base station 20 also receives a CFN value from its SFN value. To know.

Subsequently, when the handover is performed, the terminal 10 receives the SFN value from the adjacent target base station 20 and measures the difference between its CFN value and transmits it to the control station 40. The offset value and the chip offset The value (Tm) corresponding to the RRC protocol is transmitted using the RRC protocol. The control station 40 which receives this transmits the frame offset value and the chip offset value calculated to the target base station 30 so that the control station 40, the terminal 10, and the service base station 20 can also be used in the target base station 30. You can get the same CFN value as.

The CFN value should be maintained at the same value, through which data frames of the current terminal 10 can be distinguished, so that data frames from multiple base stations can be distinguished during handover, and the call can be continued without interruption. have.

2 is a diagram of data frame transmission during soft handover, and illustrates data frame transmission between base stations and a control station during handover. The downlink data frame and the uplink data frame are simultaneously displayed. The transmission of the downlink data frame and the uplink data frame are not related because the transmission of the illustrated downlink data frame and the uplink data frame is a separate channel. To show the delay time.

The control station receives an offset measurement for the target base station from the terminal and calculates and informs the frame offset so that the number of the frame to be transmitted through the cell in the target base station matches the frame number currently being transmitted. As a result, the CFNs of the illustrated control station and each base station coincide within 10 ms, and each base station has its own SFN.

The transmitting side of the data frame (control station) inserts the same CFN (for example, 150) into two paths of the cell being transmitted and the target cell to the upper user data and transmits the same. Since the delay range of about 20ms is set as margins (black display portions), when received within the margin, it is regarded as being received at the same time. In the same manner, data frames in which the same CFN is inserted are continuously transmitted in two paths every predetermined time.

The side (control station) receiving the data frame receives the same frame from the base stations with the same CFN, selects the one having the highest quality, and transmits the same frame to the upper layer.

As described above, in order to perform the handover correctly, when the terminal enters the neighboring target base station cell region, the control station accurately measures the difference between the CFN for the currently received frame and the SFN received from the cell in the target base station. You must inform.

Since the control station calculates and transmits the frame offset for the data frame to be transmitted through the cell in the target base station using only the offset information measured by the terminal, if there is an error in the measurement value transmitted by the terminal, the same data frame Since the CFNs of two connected base stations are changed, the same inter-frame selection is not made and soft handover fails.

As described above, in the conventional soft handover method, since the controller receives a value measuring the difference between the SFN of the target base station received as the terminal enters the target base station cell area and the CFN for the frame currently received, the controller uses the same without verification. If there is an error in the measurement of the terminal, the soft handover fails and there is a problem that affects the current call.

In view of the above problems, the present invention obtains the BFN of the target base station through node synchronization with the base station, obtains the CFN for the target base station by applying the measurement value received from the terminal, and then provides the existing information about the service base station. The purpose of the present invention is to provide a soft handover method of a mobile communication system for verifying that an offset measured by a terminal is accurate by comparing with a CFN.

In order to achieve the above object, the present invention relates to a frame base station (CFN) for a frame currently received by a terminal entering an adjacent target base station cell region and a target base station specific counter value (SFN) received from the target base station. Measuring the difference and transmitting it to the control station; The control station receives the terminal measurement value and calculates a frame offset for the target base station, applies it to the synchronization counter value (BFN) of the target base station to generate a CFN, and then generates the CFN of the transmission channel that is previously set and is in service. Verifying the terminal measurement value in comparison with the CFN.

The control station may further include acquiring a target base station synchronization counter value (BFN) that matches the SFN of the target base station in a 10 ms range through a node synchronization procedure with the target base station.

In addition, if the CFN values are the same as the result of the verifying step, the handover is continued. If not, the method further comprises the step of requesting re-measurement of the terminal after ending the handover.

Referring to the embodiment of the present invention configured as described above in detail.

In order to explain the present invention, it is necessary to consider the node synchronization procedure between the control station and the base station, and FIG. 3 shows a node synchronization procedure between the control station and the base station.

In order to perform the soft handover, a new transmission channel must be established between the data frame transmission layer between the target base station and the adjacent target base station in addition to the transmission channel between the control station and the existing base station. This information is received from the radio resource management layer in the control station.

In the data frame transport layer that receives the information on the transmission channel with the new base station, the BFN of the base station must be obtained first through a synchronization acquisition procedure with the new target base station.

As shown in FIG. 3, when a control station transmits an RFN value used for node synchronization to a base station through a downlink channel, the control station receiving the control station transmits a BFN used for node synchronization to the control station through an uplink channel. do.

The BFN is important in the present invention. Since the BFN coincides with the base station-specific SFN within 10 ms, the BFN can be regarded as the same counter value as the SFN in units of 10 ms.

When the synchronization acquisition procedure is performed through the data frame transport layer between the control station and the target base station, the control station may receive the BFN value and the offset value measured from the terminal. In other words, the data frame transmission layer of the control station should be inserted in the data frame transmission by correcting the frame offset (a value calculated from the measurement value received from the terminal) received from the control station radio resource management layer in the BFN of the target base station. The CFN to be calculated can be calculated, and the calculated CFN value must match the CFN previously transmitted and transmitted to the transmission channel of the serving base station.

If the two CFNs do not match, there is an error in the CFN operation for the newly established transport channel, which means that the correction by the frame offset is wrong. Here, since the frame offset is calculated using the value measured from the terminal in the radio resource management layer, it can be seen that there is an error in the measurement of the terminal.

That is, if the CFNs do not match, stopping the handover and receiving the re-measured value from the terminal in the radio resource management layer reduces the handover failure due to an abnormal frame offset.

4 is a synchronization parameter correlation diagram to which an embodiment of the present invention is applied. As shown in FIG. 4, when the handover is performed, the terminal 10 receives the SFN of the target base station, measures a difference with the existing CFN, and then controls it. Send to 40.

The control station 40 receives the data, obtains a frame offset for the target base station from the radio resource management layer, and applies the same to the received base station's BFN while establishing a new transport channel. The terminal measured values are verified by comparing with the CFN for the existing service base station transmission channel.

If the CFN values are the same as the result of the verification step, the handover continues. If the CFN values are not the same, the handover is terminated and the terminal requests re-measurement.

Although the above embodiment provides the frame offset and the chip offset to the target base station after the verification procedure, it should be noted that the verification procedure location may be changed by the control station designer, and all such changes are encompassed by the present invention.

As described above, in the soft handover method of the mobile communication system, the control station regards the BFN of the target base station obtained through node synchronization with the base station as the SFN of the target base station and obtains the frame offset obtained from the measurement value received from the terminal. The method further includes a verification step of comparing the CFN corrected by the value with the existing CFN to increase the soft handover success rate through the re-measurement of the terminal while minimizing the influence on the set call by detecting the measurement error of the terminal. There is.

1 is a synchronization parameter correlation diagram for a conventional soft handover.

2 is a data frame transmission diagram for soft handover.

3 is a node synchronization procedure diagram between a control station and a base station.

4 is a synchronization parameter correlation diagram for soft handover of the present invention.

* Description of the symbols for the main parts of the drawings *

10: terminal 20: service base station

30: target base station 40: control station

Claims (3)

A terminal entering a neighboring target base station cell region measures a difference between a frame counter value (CFN) for a frame currently received and a target base station specific counter value (SFN) received from the target base station and transmits the difference to the control station. Wow; The control station receives the terminal measurement value and calculates a frame offset for the target base station, applies it to the synchronization counter value (BFN) of the target base station to generate a CFN, and then generates the CFN of the transmission channel that is previously set and is in service. And verifying the terminal measurement value in comparison with the CFN. The mobile station of claim 1, further comprising the step of acquiring a target base station synchronization counter value (BFN) that matches the SFN of the target base station in a 10 ms range through a node synchronization procedure with the target base station. Soft handover method of communication system. The method of claim 1, further comprising: continuing the handover if the CFN values of the verification step are the same, and requesting the terminal to re-measure the terminal after the handover is finished. Soft handover method of communication system.