KR20000066773A - Method for processing a soft hand-off in an asynchronous system - Google Patents

Abstract

PURPOSE: A method for processing a soft hand-off in an asynchronous system is provided to perform the soft hand-off without a loss of data by efficiently synchronizing each base station in the asynchronous system. CONSTITUTION: If a mobile terminal located within a region of a first base station is moved to a second base station during a talk, the mobile terminal transmits a hand-off request signal and information regarding the second base station to the second base station through the first base station and a base station controller and the mobile terminal calculates a difference of a PN roll interval between first and second base stations for synchronizing the first base station and the second station to transmit the calculated difference. The second base station allocates a channel of the mobile terminal and shifts a signal channel and a traffic channel except for a pilot channel within the allocated channel according to the difference of the PN roll interval to synchronize the signal channel and the traffic channel of the first base station. The mobile terminal shifts a finger corresponding to the second base station according to the difference of the PN roll interval to synchronize the finger with a finger to the first base station.

Description

How to Handle Soft Handoff in Asynchronous Systems {METHOD FOR PROCESSING A SOFT HAND-OFF IN AN ASYNCHRONOUS SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to soft hand-off of an asynchronous wireless communication system. More particularly, the present invention relates to a soft hand-off of an asynchronous wireless communication system. The off processing method.

In general, there are two types of handoffs in a wireless communication system: softer handoff, hard handoff, and soft handoff. First, softer handoff moves from one sector to another within a cell of a sectorized base station. It is a function to change the coverage of the subscriber in the sector, and the hard handoff is an inter-frequency hand that is performed when the new base station cannot allocate the same frequency channel as the frequency currently being used while the movement by any subscriber occurs during the call. Means off. In this hard handoff process, although it is a short moment, data loss occurs at the moment of frequency changeover, and the tone is not smoothly connected. This phenomenon has a greater influence on data communication service than voice communication service. do.

In addition, soft handoff is a function of maintaining a call of a subscriber moving between cells in a base station network, and setting up a new call path through a physical link established between two base stations before disconnecting an existing call path. The above channels are operated simultaneously. Therefore, a smooth call transfer is possible so that a mobile subscriber cannot know when to change a call right.

On the other hand, in the conventional wireless communication system that performs soft handoff, the entire base station is synchronized with a global positioning system (GPS) or an exchange, and thus, each base station is also synchronized with each other, thereby enabling handoff without data loss. As mentioned above, there is a constraint that the entire system constituting the communication network (for example, each base station) must be synchronized as described above.

In contrast, an asynchronous system in which each base station is not synchronized, i.e., an asynchronous system in which a random noise code start point (PN Roll) of each base station is arbitrarily selected and a mobile terminal belonging to each base station is individually synchronized to the base station. If a soft handoff situation occurs in the system (for example, the asynchronous IMT-2000) as described in the above-described synchronous system, the current base station to which the mobile terminal belongs and the target base station to perform the handoff are not synchronized. This results in loss of data.

FIG. 1 is a diagram illustrating a pilot channel of each base station and a pilot channel of each base station in an asynchronous system in a conventional general synchronization system. Referring to FIG.

First, FIG. 1A illustrates a pilot channel for each base station in a synchronization system. As shown in the same figure, a pilot channel of each base station (A, B, C) in a synchronization system has a predetermined time interval t. Is synchronized with an integer multiple of. Therefore, even if the soft handoff is performed in the synchronization system, since the start point (PN Roll) of the PN code of the target base station can be tracked and synchronized, almost no data loss occurs.

FIG. 1B illustrates a pilot channel for each base station in an asynchronous system, in which pilot channels of each base station A ', B', and C 'in an asynchronous system are spaced at regular time intervals. Since each base station has a period for each separate pilot channel based on the point of time when each base station is initially driven, the PN Roll intervals (t ', t' ') between the base stations become irregular, and thus the handoff target Tracking and synchronizing the starting point (PN Roll) of the PN code of the base station is impossible, which causes loss of data when performing handoff.

In other words, in order to prevent loss of data when performing soft handoff in a mobile communication system, frame boundaries of call channels between base stations performing handoff must be matched (synchronized). Since the starting point is the same as the frame boundary of the call channel, each of which is synchronized with an integer multiple of a predetermined interval, it is possible to track and synchronize the starting point of the PN code of each base station performing the handoff. However, in an asynchronous system where each base station has its own PN code start point and call channel frame boundary corresponding to the initial driving time, it becomes impossible to track the PN code start point of the target base station and synchronize the call channel when performing handoff. This results in loss of data.

As a result, in order to perform a soft handoff process in an asynchronous system in which the entire system including each base station is not synchronized, the call channel between base stations performing handoff must be synchronized to prevent loss of data due to handoff. It becomes possible.

Accordingly, an object of the present invention is to provide a method for processing soft handoff in an asynchronous system capable of preventing data loss in an asynchronous wireless communication system.

In order to achieve the above object, the present invention provides a method for processing soft handoff in an asynchronous system in which each system including a plurality of base stations is not synchronized and has a separate PN sequence. Calculating a PN Roll interval between the first base station and the second base station when the mobile terminal in the mobile station moves to a second base station area; A second step of transmitting the calculated PN Roll interval and a handoff request message to the second base station; A third step of the second base station allocating a call channel for the mobile terminal based on the transmitted PN Roll interval and a handoff request message; A fourth step of the second base station shifting the interval of the frame boundary for the assigned communication channel by the PN Roll interval to synchronize with the current communication channel of the first base station; And performing a handoff of the mobile base station using the synchronized call channel.

1 is a diagram illustrating a pilot channel of each base station in a conventional general synchronization system and a pilot channel of each base station in an asynchronous system.

2 is a block diagram of an asynchronous system suitable for applying a soft handoff method according to a preferred embodiment of the present invention;

3 is a view illustrating a channel synchronization process between base stations when performing handoff in an asynchronous system according to the present invention;

4 is a flowchart illustrating a soft handoff procedure of an asynchronous system according to a preferred embodiment of the present invention.

<Description of the code | symbol about the principal part of drawing>

210: mobile terminal 220, 230: first and second base station

240: base station controller 250: switchboard

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the invention described below with reference to the accompanying drawings by those skilled in the art.

2 is a block diagram of a wireless communication system suitable for applying a soft handoff method according to a preferred embodiment of the present invention, wherein the mobile terminal 210, the first base station 220, the second base station 230, and the base station controller are shown. 240, exchanger 250.

In the same figure, the first base station 220 and the second base station 230 connected through the base station controller 240 each have a starting point (PN Roll) of any PN code. That is, since each base station has a separate PN Roll (PN code starting point) from the time according to the initial driving of each base station, each base station is not in synchronization with each other.

In an asynchronous system as shown in FIG. 2, any subscriber terminal, for example mobile terminal 210, is connected via another exchange 250 or a general public switched telephone network exchange or the same exchange 250 via an exchange 250. During the call with the subscriber, if the mobile terminal 210 moves to an area of any other base station, the mobile terminal 210 performs handoff based on the strength of the signal received from another adjacent base station together with the handoff request signal. Target base station information, for example, information about the second base station 230 is transmitted to the second base station 230 through the first base station 220 and the base station controller 240.

At the same time, the mobile terminal 210 performs a difference in the PN code between the first base station 220 and the second base station 230, that is, the first and second base stations 220, to perform a soft handoff according to the asynchronous scheme. The time difference between the PN Rolls (the starting point of the PN code) between the 230 is calculated to notify the target base station, ie, the second base station 230, to perform the handoff through the first base station 220 and the base station controller 240.

In other words, since each base station is not synchronized in the asynchronous system, the mobile terminal 210 determines the PN Roll time difference between the first base station 220 to which it belongs and the second base station 230 which is the base station of the moving area. It is calculated and sent with the handoff request signal.

When the time difference between the handoff request signal and the PN Roll is received from the mobile station 210 through the base station controller 240 through the base station controller 240, the second base station 230 moves. After allocating a call channel for performing the handoff of the terminal 210, the PN Roll of the allocated channel is shifted by a PN Roll time difference with the first base station 220, thereby The PN code start point and the PN code start point of the second base station 230 are synchronized.

In general, in a mobile communication system, a channel between a mobile terminal and a base station includes a signal channel and a traffic channel in addition to a pilot channel. FIG. 3 illustrates a handoff according to the present invention. A diagram for describing channel synchronization between time base stations will be described with reference to the accompanying drawings.

First, the pilot channel is a channel of the base station, and all mobile terminals located within the range of one base station have the same pilot channel period. In addition, the signal channel and the traffic channel may be referred to as channels for transmitting and receiving actual data through each base station through the assigned channel. Therefore, in the above-described process, shifting the frame boundary of the call channel so that the second base station 230 synchronizes with the first base station 220 may cause the signal channel and the traffic channel other than the pilot channel to be present in the assigned channel. This means shifting by the PN Roll time difference ε to be synchronized with the signal channel and the traffic channel of the base station 220.

In detail, FIG. 3A illustrates a pilot channel P ₁ and a signal channel S ₁ from a first base station 220, a traffic channel T ₁ , and a pilot channel from a second base station 230 before performing a handoff. (P ₂ ) and signal channel (S ₂ ), traffic channel (T ₂ ) is shown, the first base station 220 and the second base station 230 before the handoff is performed as shown in the figure The PN Roll and frame boundaries for each channel P ₁ and P ₂ , S ₁ and S ₂ , T ₁ and T ₂ in are spaced apart by a predetermined interval (ie, time difference ε). This is not a problem when the spaced interval ε is a minimum interval that can prevent data loss during handoff. However, in the asynchronous system, as described above, since the starting point of the PN roll of each base station is irregular, the spaced interval ( [epsilon] may be outside the minimum range to prevent data loss during handoff.

Accordingly, in order to perform a handoff without data loss, the mobile terminal 210 in the asynchronous system calculates the PN Roll time difference ε between the first base station 220 and the second base station 230 to determine the first base station 220 and The base station controller 240 notifies the second base station 230. And, the second base station 230 is based on the PN Roll time difference (ε) provided from the mobile terminal 210 as shown in Figure 3b except for the pilot channel (P ₂ ) and the signal channel (S ₂ ) and traffic channels By shifting the frame boundary of T ₂ by [epsilon], it is synchronized with the signal channel S ₁ and the traffic channel T _{1 of} the first base station 220.

On the other hand, a mobile terminal typically has two or more fingers therein to process data transmitted / received from the current base station when performing handoff and data transmitted / received from the target base station to perform handoff in separate fingers. Next, the signals of the two base stations processed by the respective fingers are combined. The signal channel S ₁ and the traffic channel T ₁ of the first base station 220 and the second base station 230 are processed through the process described above. When the signal channel S ₂ and the traffic channel T ₂ are synchronized, the mobile terminal 210 sets the frame boundary (signal, traffic frame) of the finger for the second base station 230 to the two base stations 220 and 230. The frame boundary (signal, traffic frame) of the finger corresponding to each of the base stations 220 and 230 is synchronized by shifting by the PN Roll interval ε between them.

As a result, when a soft handoff occurs in the asynchronous system, the mobile terminal 210 calculates a PN Roll interval ε for each base station and notifies the second base station 230, and the second base station 230 By synchronizing with the first base station 220 based on the PN Roll interval ε, it is possible to prevent the loss of data generated during soft handoff.

4 is a flowchart illustrating a soft handoff process of an asynchronous system according to a preferred embodiment of the present invention. A series of processes according to the soft handoff processing method described above with reference to FIG.

First, when the mobile terminal 210 in the area of the first base station 220 moves to the area of the second base station 230 during the call (step 401), the mobile terminal 210 receives the handoff request signal and the second base station. Information about the 230 is transmitted to the second base station 230 through the first base station 220 and the base station controller 240, wherein the mobile terminal 210 is the first base station 220 and the second base station ( In order to synchronize the 230, a PN Roll interval difference ε between each of the base stations 220 and 230 is calculated and transmitted together (step 403).

In this case, after the second base station 230 allocates a channel of the mobile terminal 210 (step 405), the difference between the PN Roll interval from the mobile terminal 210 and the signal channel except for the pilot channel in the assigned channel is different from the mobile terminal 210. By shifting by [epsilon], the signal channel of the first base station 220 and the traffic channel are synchronized (step 407). In addition, the mobile terminal 210 shifts a finger corresponding to the second base station 230 of each finger provided therein by a PN roll interval difference ε to synchronize with the finger for the first base station 220. The handoff is processed (step 409).

As described above, the present invention has been described and illustrated with reference to the preferred embodiments, but it will be apparent to those skilled in the art that various modifications may be made without departing from the spirit of the present invention.

As described above, according to the present invention, it is possible to efficiently synchronize each base station in an asynchronous system to perform soft handoff without loss of data, and a synchronous clock required for synchronization between base stations in a conventional synchronous system. By excluding the means of generation (e.g., satellites associated with GPS), there is an effect that can reduce the design cost and the ease of asynchronous system design.

Claims (4)

A soft handoff processing method of an asynchronous system in which each system including a plurality of base stations is not synchronized and has a separate PN period, A first step of calculating a PN Roll interval between the first base station and the second base station when the mobile terminal in the first base station area moves to the second base station area; A second step of transmitting the calculated PN Roll interval and a handoff request message to the second base station; A third step of the second base station allocating a call channel for the mobile terminal based on the transmitted PN Roll interval and a handoff request message; A fourth step of the second base station shifting the interval of the frame boundary for the assigned communication channel by the PN Roll interval to synchronize with the current communication channel of the first base station; And a fifth step of performing a handoff of the mobile base station using the synchronized call channel. The method of claim 1, The PN Roll interval is calculated in the mobile terminal soft handoff processing method of the asynchronous system. The method of claim 1, And the communication channel shifted in the fourth step is a signal channel and a traffic channel allocated from the second base station except for a pilot channel. The method of claim 3, wherein In the fourth step, the mobile terminal also shifts a frame boundary between a signal and a traffic channel of an internal finger corresponding to the second base station in response to the signal channel and the traffic channel shifted in the second base station. Soft handoff processing method of the asynchronous system further comprising.