KR100369321B1 - Method for handover from 3G communication system to 2G communication system - Google Patents

Abstract

The present invention provides a handover method from a third generation W-CDMA communication system to a second generation IS-95 CDMA system. The present invention distinguishes each base station by using a phase difference of the same pilot code with respect to a reference time. In the first step of acquiring initial synchronization and searching for a cell, when a 3G / 2G dual-mode terminal performs handoff from a 3G W-CDMA system to a 2G IS-95 CDMA system, If there is no time information of the second generation IS-95 CDMA system as a result of the determination of the second step and the second step of determining whether there is time information, the third generation W-CDMA is obtained by acquiring the common system time of the second generation IS-95 CDMA system. By including a third step of performing a handoff by aligning the radio frame of the system according to the time of the second generation IS-95 CDMA system, the second generation IS- in the third generation W-CDMA system in the third generation / second generation dual-mode terminal 95 CDMA Sheath It is possible to perform a handover to the system.

Description

Handover method from 3rd generation communication system to 2nd generation communication system {Method for handover from 3G communication system to 2G communication system}

The present invention relates to a handover method from a third generation communication system to a second generation communication system. In particular, a second generation in which an asynchronous wideband code division multiple access (W-CDMA) base station, which is a third generation mobile communication system, is currently commercialized. (2 Generation) 2nd generation IS- in 3rd generation W-CDMA system by aligning radio frames of 3rd generation W-CDMA system with 2nd generation synchronous CDMA absolute time using forward channel of IS-95 Code Division Multiple Access (CDMA) system The present invention relates to a handover method from a third generation communication system to a second generation communication system suitable for performing a handover to a 95 CDMA system. An IS-95 based narrowband CDMA system currently commercially available is a GPS (Global Positioning) method. System) A synchronous system in which all base stations operate at the system time using a receiver, designed for voice or low speed data-based communication. A stem. On the other hand, the W-CDMA system currently being developed by the 3rd Generation Partnership Project (3GPP) is basically an asynchronous system that does not use a GPS receiver and has a base station time, that is, a starting point of a 10 ms radio frame, independent of each other. And a multimedia service of high-speed data communication. Thus, when an operator performing a conventional IS-95 CDMA-based cellular or PCS service adopts a W-CDMA-based third generation mobile communication system, It is very advantageous in terms of initial investment savings that the cell design is centered on large cities, which are densely populated.

Handover between conventional IS-95 A / B systems and G3G DS (Direct Sequence CDMA) systems does not support voice and circuit data calls or high-speed packet data calls in the current architecture. As an alternative, 3GPP2 (3rd Generation Partnership Project 2) inserts a scheme for service negotiation before handoff, and the procedure criteria uses the procedure in synchronization, and only in the wireless section. Considering how to follow asynchronous.

And handover between IS-95 A / B system and G3G MC system is partially possible. A concrete case of this will be described below with an example of a voice call.

1) When a second generation terminal receives a service from a third generation W-CDMA system and then hands off to a second generation IS-95 CDMA system:

By default, the MC3x is 100% compatible with IS-95 A / B systems in Radio Configuration 1 and 2. That is, since the physical channels, the pilot, synchronization, paging, and traffic channels are used in the same specification in both systems, if the handoff is performed at the same frequency, soft handoff is possible.

2) When a third generation terminal receives a service from a third generation W-CDMA system and then hands off to a second generation IS-95 CDMA system:

In this case, the third generation terminal operates with one of the wireless configurations 6, 7, 8, and 9. Therefore, handoff is impossible because the channel structure of the fundamental channel (FCH) is different.

3) When a second generation terminal receives a service from a second generation IS-95 CDMA system and then hands off to a third generation W-CDMA system:

By default, the MC3x is 100% compatible with IS-95 A / B systems in wireless configurations 1 and 2. That is, since the physical channels, the pilot, synchronization, paging, and traffic channels are used in the same specification in both systems, if the handoff is performed at the same frequency, soft handoff is possible.

4) When a 3rd generation terminal receives service from a 2nd generation IS-95 CDMA system and hands off to a 3rd generation W-CDMA system:

In this case, the third generation terminal operates with one of the wireless configurations 6, 7, 8, and 9. Therefore, handoff is impossible because the channel structures of the FCH (Fundamental Channel) are different. That is, in the case of the IS-95 CDMA system, the reference time of all base stations is matched, so that the phase difference of the same pilot code with respect to the reference time Distinguish each base station (see FIGS. 5A, 5B, and 5C). This feature of the second generation IS-95 CDMA system allows the terminal to perform pilot discovery of neighboring base stations in a very short time, either in the active or idle state of the terminal. To do it. In contrast, since the terminal does not know the system synchronization during the initial cell search, the initial synchronization acquisition time is very long compared to the synchronization acquisition time for the neighboring cell in the active or idle state. However, the initial synchronization acquisition process of the terminal is relatively less important than the discovery process of the neighbor cell for handoff, and it is relatively less important than before the call is established. Generation 3 W-CDMA System The 3G / 2G dual-mode terminals, which are receiving 3G services in the wireless networks in which the base station systems are used independently, must go through the same procedure as the initial synchronization acquisition process in the 2G IS-95 CDMA system. Therefore, the cell search time may take several hundred msec or more. In this case, calls requiring low latency such as voice service or line data service are disconnected. If the system time of the third generation W-CDMA system and the second generation IS-95 CDMA system is independent of each other, the third generation / second generation terminal is the third generation. The time taken to search one cycle of the second generation IS-95 CDMA pilot PN in the compressed mode is shown in Equation 1 below. Where K is the number of virtual tests set per chip to obtain search time, L is the length of the main correlator (typically 64 chips), and T _async is the size of the search window, which is the length of the pilot PN sequence, which is 26.666 ms. . D is the duty factor of the compression mode in the third generation W-CDMA system, which is generally 8/20 in the compression mode pattern 5. N is the number of parallel correlators, generally eight.

As described above, when the third generation terminal is used, there is a problem that the second generation DCS (Digital Cross-connect System) / PCS (Personal Communication System) network and the third generation mobile communication network are not compatible.

Accordingly, the present invention has been proposed to solve the conventional problems as described above, and an object of the present invention is to use a forward channel of a second generation IS-95 CDMA system, which is currently commercialized, by an asynchronous W-CDMA base station, which is a third generation mobile communication system. 3rd generation W-CDMA communication system that can perform handover from 3rd generation W-CDMA system to 2nd generation IS-95 CDMA system by aligning radio frames of 3rd generation W-CDMA system with 2nd generation synchronous CDMA absolute time To provide a handover method to a second generation IS-95 CDMA system. A person skilled in the art to which the present invention pertains may have other aspects of the present invention from the drawings, the detailed description of the invention, and the claims. The purpose and advantages can be easily recognized.

In order to achieve the above object, the present invention, in the third generation W-CDMA communication system applied to the base station of the third generation W-CDMA system including a receiver capable of receiving a second generation IS-95 CDMA forward channel signal In a handover method to a generation IS-95 CDMA system, a first stage, a third generation, a second generation dual generation that acquires initial synchronization and searches for a cell by distinguishing each base station by using a phase difference of the same pilot code with respect to a reference time Step 2 of determining whether there is time information of the second-generation IS-95 CDMA system when the mode terminal is handed off from the third-generation W-CDMA system to the second-generation IS-95 CDMA system, and the determination result of the second step 2 If there is no time information of the second-generation IS-95 CDMA system, the common system time of the second-generation IS-95 CDMA system is obtained, and the radio frame of the third-generation W-CDMA system is aligned with the time of the second-generation IS-95 CDMA system. Five And a third step of executing a second generation using a pilot channel and a synchronization channel of the largest signal from an adjacent second generation IS-95 CDMA system base station through the second generation IS-95 CDMA signal receiving unit. An eleventh step of acquiring a common system time of the IS-95 CDMA system, a twelfth step of aligning a boundary of a radio frame with a common system time of the second generation IS-95 CDMA system obtained in the eleventh step, and the first step It exists between the 2nd generation IS-95 CDMA forward signal and the 2nd generation IS-95 CDMA system base station time received by the 3rd generation W-CDMA system base station based on the common system time of the 2nd generation IS-95 CDMA system obtained in step 11. A handover method from a third generation W-CDMA communication system to a second generation IS-95 CDMA system comprising a thirteenth step of transmitting a signal to the third generation / second generation dual mode terminal by advancing a one-way time delay Provided.

1 is a configuration diagram of a second generation / 3 generation hybrid communication system to which the present invention is applied;

FIG. 2 is a detailed block diagram of a third generation W-CDMA system base station in FIG. 1;

3 is an overall flowchart illustrating a handover procedure from a third generation W-CDMA communication system to a second generation IS-95 CDMA system according to the present invention;

FIG. 4 is a detailed flowchart illustrating the handover step from the 3rd generation W-CDMA system to the 2nd generation IS-95 CDMA system in FIG. 3 to synchronize the forward channel of the 3rd generation W-CDMA system with the 2nd generation IS-95 CDMA system time. Flow chart showing the process of

5 is a graph illustrating a forward channel frame structure of a third generation W-CDMA system and a forward channel frame structure of a second generation IS-95 CDMA system according to FIG. 4;

FIG. 6 is a detailed flowchart illustrating a handover step from a third generation W-CDMA system to a second generation IS-95 CDMA system in FIG.

FIG. 7 is a graph showing a frame structure for explaining long code time alignment of a second generation IS-95 CDMA system for handover according to FIG.

Description of the main parts of the drawing

10: 2nd generation IS-95 CDMA system cell 11: 2nd generation IS-95 CDMA system base station

20: 3rd generation W-CDMA system cell 21: 3rd generation W-CDMA system base station

22: 2nd generation IS-95 CDMA signal receiver

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same components have the same number as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a second generation and third generation hybrid communication system to which the present invention is applied. FIG. 2 is a detailed block diagram of a third generation W-CDMA system base station in FIG.

Here, reference numeral 10 is a cell structure of a second generation IS-95 CDMA system, 11 is a second generation IS-95 CDMA system base station of a second generation IS-95 CDMA system, and 20a and 20b are cell structures of a third generation W-CDMA system. 21a and 21b are 3rd generation W-CDMA system base stations of the 3rd generation W-CDMA system, and 22 are located in the 3rd generation W-CDMA system base station 21 and receive signals from the 2nd generation IS-95 CDMA system. 2nd generation IS-95 CDMA signal receiving unit. The 3rd generation W-CDMA system base station 21 includes a 2nd generation IS-95 CDMA signal receiving unit 22 for receiving the 2nd generation IS-95 CDMA forward channel as shown in FIG. The second generation IS-95 CDMA signal receiver 22 is used to obtain a second generation CDMA common system time by using a pilot channel and a synchronization channel of the largest signal among the signals received from the adjacent second generation CDMA base station.

In this environment, 3G / 2G dual-mode terminals are mandatory, and handover from 3G W-CDMA system to 2G IS-95 CDMA system is a prerequisite. This is a general flowchart showing the handover procedure from the CDMA communication system to the second generation IS-95 CDMA system.

As shown in Fig. 3, when the 3G / 2G dual-mode terminal is handed off from the 3G W-CDMA system to the 2G IS-95 CDMA system, the 3G W-CDMA base station 21 receives a reference time. A first step (ST1) (ST2) of acquiring initial synchronization and searching for a cell by distinguishing each base station by using a phase difference of the same pilot code for? A second step ST3 (ST4) for determining whether there is time information of the second generation IS-95 CDMA system; As a result of the above determination, if there is no time information of the second generation IS-95 CDMA system, the system time of the second generation IS-95 CDMA system is acquired to match the radio frame of the third generation W-CDMA system with the time of the second generation IS-95 CDMA system. A third step ST5 of performing alignment and handoff is performed. FIG. 4 is a flowchart illustrating a handover step from the third generation W-CDMA system to the second generation IS-95 CDMA system in FIG. 3 in detail. Flow diagram illustrating a process of synchronizing a forward channel of a CDMA system with a second generation IS-95 CDMA system time.

As shown in Fig. 4, in the third step ST5, the 3rd generation W-CDMA system base station 21 is connected to the 2nd generation IS-95 CDMA system base station through the 2nd generation IS-95 CDMA signal receiving unit 22. An eleventh step (ST11) of acquiring the common system time of the second-generation IS-95 CDMA system using the pilot channel and the synchronization channel of the largest signal from 11); A twelfth step ST12 of aligning a boundary of a radio frame with a common system time of the second generation IS-95 CDMA system obtained in the eleventh step; Second generation IS-95 CDMA forward signal and second generation IS-95 CDMA system received by the third generation W-CDMA system base station 21 based on the common system time of the second generation IS-95 CDMA system obtained in step 11 above. A thirteenth step (ST13) of transmitting a signal to the third generation / second generation dual mode terminal by advancing by one way delay existing between the base station time is performed.

When the third generation W-CDMA system base station 21 performs alignment in the twelfth step ST12, the start point and the third generation W of the synchronization channel superframe corresponding to the '0' pilot offset of the second generation IS-95 CDMA system are aligned. Align with a frame with a frame number that is a multiple of 8, including a '0' in the CDMA system.

In addition, in the thirteenth step ST13, the one-way delay, that is, the distance between the second-generation IS-95 CDMA system base station 11 and the third-generation W-CDMA system base station 21 and the one-way time delay are 3 The call channel message of the forward link received by the second-generation IS-95 CDMA signal receiver 22 in the generation W-CDMA system base station 21 is calculated based on a field indicating latitude and a field indicating longitude of the base station.

FIG. 5 is a graph illustrating a forward channel frame structure of a third generation W-CDMA system and a forward channel frame structure of a second generation IS-95 CDMA system according to FIG. 4; The third generation W-CDMA system base station 21 having obtained the common system time of the IS-95 CDMA system aligns the 10 msec radio frame boundary with the second generation IS-95 CDMA system time. According to the present invention, the third generation Instead of using the pilot channel and the synchronization channel of the second-generation IS-95 CDMA forward link, the W-CDMA system base station 21 obtains the base station time (or GPS reference time) of the second-generation IS-95 CDMA system by using a GPS receiver. The boundary of the 10 msec radio frame of the third generation W-CDMA system may be aligned with the common system time of the second generation IS-95 CDMA system. This arrangement is shown in Fig. 5. The third-generation W-CDMA system base station 21 receives the 10 msec radio frame boundary at the common system time of the second-generation IS-95 CDMA system received by the third-generation W-CDMA system base station 21. Arrangement, but multiples of 8, including the starting point of the sync channel super frame corresponding to the '0' pilot offset of the second generation IS-95 CDMA system and the '0' of the third generation W-CDMA system as shown in FIG. Align with the frame having the frame number corresponding to. In the third generation W-CDMA system, frame numbers are defined from 0 to 71.

On the other hand, as shown in Figure 1, the position of the base station of the third generation W-CDMA system and the base station position of the second generation IS-95 CDMA system in the second generation and third generation hybrid cellular system is generally different. Therefore, the second generation forward signal received by the third generation W-CDMA system base station 21 is a one-way time delay as shown in FIG. 1 with respect to the second generation IS-95 CDMA system base station 11 time (or GPS reference time). (One way delay, 3usec / km), which is proportional to the distance between the corresponding second generation IS-95 CDMA system base station 11 and the third generation W-CDMA system base station 21, and the second generation cell radius is Downtown areas within 1 km are generally smaller than 3usec.

The 3rd generation W-CDMA system base station 21 advances the 10msec radio frame boundary of the 3rd generation forward link by one way delay as shown in FIG. 5D for the received 2nd generation IS-95 CDMA system time. To calculate a one-way delay based on the distance between the second-generation IS-95 CDMA system base station 11 and the third-generation W-CDMA system base station 21. The 3rd generation W-CDMA system base station 21 may use a paging channel of a 2nd generation CDMA forward link. The 2nd generation IS-95 CDMA system base station 11 includes a call channel message of a 2nd generation CDMA forward link. A BASE_LAT field indicating a latitude and a BASE_LONG field indicating a longitude, wherein the third generation W-CDMA system base station 21 includes a corresponding second generation IS-95 CDMA system base station 11 included in a call channel message of the second generation CDMA. Latitude and Sir The distance information and its one-way delay with the second generation IS-95 CDMA system base station 11 can be calculated using the FIG. Information. FIG. 6 shows the second generation IS in the third generation W-CDMA system of FIG. FIG. 7 is a detailed flowchart illustrating a handover step to a -95 CDMA system, and FIG. 7 is a graph showing a frame structure for explaining a long code time alignment of a second generation IS-95 CDMA system for handover according to FIG.

As shown in Fig. 6, in the third step ST5, the third generation W-CDMA system base station 21 is adjacent to the second generation IS-95 CDMA system through a call channel or a wired network of the second generation IS-95 CDMA forward link. A twenty-first step ST21 of obtaining pilot PN offset information for the base stations 11; A twenty-second step of transmitting a pilot PN offset value for the second generation IS-95 CDMA system base station 11 to the third generation / second generation dual mode terminal through the third generation forward channel (ST22); The second-generation IS-95 CDMA system by searching for the pilot channel of the second-generation IS-95 CDMA forward link (ST23) by using the received pilot PN offset value and the third-generation W-CDMA / 2-generation IS-95 CDMA system synchronization Receiving the offset value of the pilot signal and the strength of the pilot signal from the third generation / second generation dual mode terminal obtained the pilot signal of the base station 11, and the received signal from the second generation IS-95 CDMA system base station 11 If the pilot strength transmitted to the 3rd generation W-CDMA system base station 21 exceeds the threshold, the system keeps track of the system and instructs the 3rd generation / 2nd generation dual-mode terminal to handoff to the 2nd generation IS-95 CDMA system. A 25 th step (ST26) (ST27) of establishing a call with the 2nd generation IS-95 CDMA system base station 11 by transmitting the long code state information of the 2nd generation IS-95 CDMA system to the terminal through the forward channel. This allows the second generation of IS-95 CDMA The system base station 11 sets up a second generation IS-95 CDMA forward call channel, and the third generation / second generation dual mode terminal demodulates a forward call channel from the second generation IS-95 CDMA system base station 11 and simultaneously. By setting the second generation IS-95 CDMA reverse talk channel, the second generation IS-95 CDMA system base station 11 completes the handoff procedure by performing steps ST28 and ST29 to demodulate the reverse talk channel.

The third generation W-CDMA system base station 21 acquires pilot PN offset information for adjacent second generation IS-95 CDMA system base stations 11 through a call channel or wired network of the second generation IS-95 CDMA forward link, and 3 The generation W-CDMA system base station 21 generates a pilot PN offset value for adjacent generation 2 IS-95 CDMA system base stations 11 through the generation 3 forward channel in the generation 3 IS-95 CDMA system in the generation 3 W-CDMA system. It transmits to the 3rd generation / 2 generation dual mode terminal which is going to handover.

The 3rd generation / second generation dual-mode terminal, which obtains pilot PN offset information for neighboring second generation IS-95 CDMA system base stations 11 through one channel of the third generation forward link, uses this value and the third generation / second generation IS- The pilot channel of the second generation CDMA forward link is searched using a 95 CDMA system synchronization structure.

Here, in the 3G / 2G IS-95 CDMA system synchronization structure, the 3G / 2G terminal searches for the 2G pilot channel in the 2G IS-95 CDMA system itself. It is almost similar to the process of acquiring a dictionary and searching for adjacent cells.

The terminal acquiring the pilot signal of the 2nd generation IS-95 CDMA system base station 11 sends the pilot offset value and the pilot strength to the 3rd generation W-CDMA system base station 21 and the 2nd generation IS-95 CDMA system base station 11 Keep track of the 20msec system time of the signal received from

During the tracking, the 3rd generation W-CDMA system base station 21 receives the pilot offset value and the pilot strength information from the terminal, and instructs the terminal to handoff to the second generation IS-95 CDMA system when the pilot strength exceeds a certain threshold. .

2nd generation IS-95 CDMA to establish a call with the 2nd generation IS-95 CDMA system base station 11 after the terminal acquires identification of a cell to be handed off with the pilot channel of the 2nd generation IS-95 CDMA system and 20 msec frame synchronization It should be synchronized with the long PN code of the system. This transmits the long code state information of the second generation IS-95 CDMA system to the terminal through the third generation forward channel, as shown in FIG. The terminal which has received the long code state information from the 3rd generation W-CDMA system base station 21, as shown in Fig. 7, uses the long code state information in the corresponding part of the 20msec 2nd generation IS-95 CDMA system time locked by the long code state information. Initialize

The 2nd generation IS-95 CDMA system base station 11 receives the handoff command of the 3rd generation / 2nd generation terminal from the upper network and establishes the 2nd generation IS-95 CDMA forward call channel. The terminal demodulates the forward call channel from the second-generation IS-95 CDMA system base station 11 and simultaneously establishes the second-generation IS-95 CDMA reverse call channel so that the second-generation IS-95 CDMA system base station 11 performs the reverse call channel. Demodulate.

According to the present invention, when the third generation W-CDMA system operates in synchronization with the second generation IS-95 CDMA system, the time taken for the third generation / second generation terminal to search neighboring base stations once in the third generation compression mode is as follows. Equation 2

Herein, it is assumed that the terminal obtains information on pilot PN offset values of neighboring second generation synchronous base stations from the third generation W-CDMA system base station 21 in advance.

K is the number of virtual tests set per chip to obtain search time, L is the length of the main correlator (typically 64 chips), T _sync is the size of the search window, less than 40usec, and D is the third generation W-CDMA system. The duty factor of the compression mode, which is generally 8/20 in compression mode pattern 5. R is the number of adjacent second generation IS-95 CDMA cells up to 20 cells and N is generally 8 as the number of parallel correlators.

As described above, the present invention aligns the radio frame of the 3rd generation W-CDMA system with the 2nd generation synchronous CDMA absolute time using the forward channel of the 2nd generation IS-95 CDMA system to the 2nd generation IS-95 CDMA system. It will be able to perform a handover.

Although the preferred embodiment of the present invention has been described above, the present invention may use various changes, modifications, and equivalents. It is clear that the present invention can be applied in the same manner by appropriately modifying the above embodiments. That is, it can be used in any field where global roaming must be stably operated between the 3rd generation W-CDMA system and the existing 2nd generation IS-95 CDMA system. Accordingly, the above description does not limit the scope of the invention as defined by the limitations of the following claims.

As described above, the handover method from the 3rd generation W-CDMA communication system to the 2nd generation IS-95 CDMA system according to the present invention provides backward compatibility between the existing 2nd generation DCS / PCS network and the 3rd generation mobile communication network. There will be an industrial use effect to continue the development of 3rd generation W-CDMA systems while maintaining the existing 2nd generation IS-95 CDMA systems that can be enabled.

Claims (5)

A handover method from a 3rd generation W-CDMA communication system applied to a base station of a 3rd generation W-CDMA system including a receiver capable of receiving a 2nd generation IS-95 CDMA forward channel signal, to a 2nd generation IS-95 CDMA system In A first step of identifying each base station by using a phase difference of the same pilot code with respect to a reference time to obtain initial synchronization and searching for a cell; A second step of determining whether there is time information of the second generation IS-95 CDMA system when the third generation / second generation dual mode terminal performs handoff from the third generation W-CDMA system to the second generation IS-95 CDMA system; And If there is no time information of the second-generation IS-95 CDMA system as a result of the determination in the second step, the common frame time of the second-generation IS-95 CDMA system is obtained to convert the radio frame of the third-generation W-CDMA system to the second-generation IS-95 CDMA system. Step 3 to perform handoff by aligning with the time of the system Including but not limited to: The third step is An eleventh step of acquiring a common system time of a second generation IS-95 CDMA system using a pilot channel and a synchronization channel of the largest signal from an adjacent second generation IS-95 CDMA system base station through the second generation IS-95 CDMA signal receiving unit; ; A twelfth step of aligning a boundary of a radio frame with a common system time of the second generation IS-95 CDMA system obtained in the eleventh step; And Second generation IS-95 CDMA forward signal and second generation IS-95 CDMA system base station time received by the third generation W-CDMA system base station based on the common system time of the second generation IS-95 CDMA system obtained in step 11 A thirteenth step of transmitting a signal to the third generation / second generation dual mode terminal by advancing by a one-way time delay existing between A handover method from a third generation W-CDMA communication system to a second generation IS-95 CDMA system. delete The method of claim 2, The twelfth step Aligning a frame having a frame number corresponding to a multiple of 8 including a start point of a synchronization channel superframe corresponding to a '0' pilot offset of the second generation IS-95 CDMA system and a '0' of the third generation W-CDMA system that A handover method from a third generation W-CDMA communication system to a second generation IS-95 CDMA system. The method of claim 2, The one-way time delay is 2nd generation IS-95 CDMA system base station and 3rd generation based on the field indicating the latitude and the longitude field of the base station in the call channel message of the second generation IS-95 CDMA forward link received by the second generation IS-95 CDMA signal receiver; Calculated by calculating the distance between base stations in W-CDMA system A handover method from a third generation W-CDMA communication system to a second generation IS-95 CDMA system. The method of claim 1, The third step is Acquiring pilot PN offset information for an adjacent second generation IS-95 CDMA system base station through a call channel or a wired network of the second generation IS-95 CDMA forward link; Transmitting a pilot PN offset value for a second generation IS-95 CDMA system base station to a third generation / second generation dual mode terminal through a third generation forward channel; And Pilot of the second generation IS-95 CDMA system base station by searching for the pilot channel of the second generation IS-95 CDMA forward link using the received pilot PN offset value and the third generation W-CDMA / 2 generation IS-95 CDMA system synchronization Receiving the offset value of the pilot signal and the strength of the pilot signal from the third generation / second generation dual mode terminal acquiring the signal, and if the strength of the pilot signal exceeds the threshold, the second generation to the third generation / second generation dual mode terminal Initiates a handoff to the IS-95 CDMA system and establishes a call with the second-generation IS-95 CDMA system base station 11 by transmitting the long code state information of the second-generation IS-95 CDMA system to the terminal through the third-generation forward channel. 23rd step By including more The second generation IS-95 CDMA system base station establishes a second generation IS-95 CDMA forward call channel, and the third generation / second generation dual mode terminal demodulates a forward call channel from the second generation IS-95 CDMA system base station. And simultaneously setting up a second generation IS-95 CDMA reverse call channel so that the second generation IS-95 CDMA system base station demodulates the reverse call channel to complete the handoff procedure. A handover method from a third generation W-CDMA communication system to a second generation IS-95 CDMA system.