JP2003501871A - Apparatus and method for performing handoff in mobile communication system having short synchronization channel - Google Patents

Abstract

(57) Abstract: A base station communication apparatus and method in a synchronous mobile communication system having a forward short synchronization channel for generating a PN_OFFSET signal is provided. A method for performing a handoff when a mobile station moves from a cell of an asynchronous base station with which a mobile station is communicating to a cell of a synchronous base station, wherein the mobile station is assigned to the synchronous base station for a predetermined time. Receiving a PN_OFFSET signal indicating a specific PN_OFFSET value from the synchronous base station, reporting the PN_OFFSET value to the asynchronous base station, and receiving the system information for the synchronous base station from the asynchronous base station. And performing a handoff of the synchronous base station to the cell based on the received system information.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD OF THE INVENTION

The present invention relates to an apparatus and method for performing handoff in a mobile communication system, and more particularly, to a new apparatus and method for performing handoff when a mobile station moves from a cell of an asynchronous mobile communication system to a cell of a synchronous mobile communication system. Regarding the method.

[0002]

[Prior art]

The asynchronous mobile communication system is, for example, the U standard adopted as a European standard.
The mobile communication system can be MTS, and the synchronous mobile communication system can be IMT-2000 adopted as an American standard. These systems tend to become more and more harmonious, and accordingly, various technologies compatible with each other have been required. One such technique relates to handoffs that can occur between the synchronous and asynchronous mobile communication systems.

The handoff is performed while a call service in a mobile communication system is being performed.
It is a technique that allows a user to continuously receive a call service without interruption when a mobile station moves from a cell currently in communication to an adjacent cell. The handoff is divided into a soft handoff and a hard handoff. In the soft handoff, the mobile station holds a call using the channel assigned by the target base station and the channel assigned by the currently serving base station. Eventually, the mobile station cuts off one of the two channels whose channel quality is lower than the pilot strength reference value. In the hard handoff, the channel allocated by the currently serving base station is first released and then a connection to a neighboring base station is attempted.

To date, handoff techniques have evolved around synchronous mobile communication systems. However, with the advent of asynchronous mobile communication systems, research on handoff between synchronous and asynchronous mobile communication systems is in progress. In general, the mobile station acquires information about a neighboring cell when a pilot signal received from one of the neighboring cells has a strength equal to or higher than a reference value or a base station requests it. The information is reported to the base station. The information transmitted to the base station is used as information for a handoff performed when the mobile station moves from a currently communicating cell to a neighboring cell while a call service is being performed.
The base station transmits information for handoff through a paging channel (for synchronous communication system) or a broadcast channel (for asynchronous communication system). Hard handoff normally occurs when the mobile station moves from a cell of an asynchronous mobile communication system to a cell of a synchronous mobile communication system. In the case of the hard handoff, the mobile station disconnects the call service from the asynchronous mobile communication system while acquiring the information on the neighboring cells.

Conventionally, a mobile station should perform the following process in order to interpret information for a synchronous mobile communication system. First, the mobile station interprets the sync signal message stored in the sync signal frame transmitted from the sync channel of the sync mobile communication system. The transmission bit per 80 ms frame of the sync signal frame is 96 bits, and the length of the sync signal message including information that enables the mobile station to communicate with the synchronous mobile communication system is 221 bits. Therefore, the mobile station needs at least 240 ms (80 ms x 3) to interpret the message. The above-mentioned specifications are related to the TIA that defines the synchronous mobile communication system.
/ EIA-IS-2000.5 standard.

Hereinafter, the base station of the synchronous mobile communication system is referred to as “synchronous base station”, and the base station of the asynchronous mobile communication system is referred to as “asynchronous base station”. FIG. 3 shows a procedure in which a mobile station currently in communication with an async base station acquires information about an adjacent sync base station. Referring to FIG. 3, in step 301, the mobile station receives from the async base station an information retrieval message of a sync base station adjacent to the async base station. Then, in step 303, the mobile station starts an information search for the adjacent synchronization base station, and in step 305, detects a pilot signal from the adjacent synchronization base station. In step 307, the mobile station determines whether the pilot signal having the maximum peak value is detected. If the pilot signal having the maximum peak value cannot be detected, the mobile station returns to step 305. If the maximum peak value of the pilot signal is detected, the mobile station proceeds to step 309 to receive a sync frame from the forward sync channel from the sync base station in which the pilot signal having the maximum peak value is detected. In such a case, the mobile station must receive at least three sync frames from the sync base station to receive all sync signaling messages. For example, the mobile station needs at least 240 ms to receive a sync frame from a sync base station having a channel structure as shown in FIG. 2, and communicates with the async base station during a reception time of the frame. To cut off. Therefore, if the procedure of FIG. 3 is performed for a long time, detrimental results such as loss of data communicated between the async base station and the mobile station may occur.

Conventionally, the forward channel of the synchronous base station has a structure as shown in FIG. Referring to FIG. 2, the forward channels include a forward pilot channel 203 that generates a pilot signal, a forward synchronization channel 204 that generates a synchronization signal, and
A forward dedicated control channel 202 for generating a dedicated channel control message,
It includes a forward-only basic channel 207 for generating a voice signal and a forward-only additional channel 208 for generating packet data. The structure and operation of each channel are described in Korean Patent Application No. 1998-113 previously filed by the present applicant.
No. 81 discloses in detail.

FIG. 11 shows a handoff procedure according to the prior art when a mobile station moves from a cell of an asynchronous base station to a cell of a synchronous base station as shown in FIG. Referring to FIG. 11, in step 1101, the mobile station B transmits a message including information to other base stations adjacent to the asynchronous base station A through the broadcast channel (in the asynchronous communication system) or the paging channel (in the synchronous communication system). It is received from the asynchronous base station A. In step 1102, the mobile station measures the reception strength of the pilot signal transmitted from the neighboring base station and transmits a message including the measurement result of the pilot signal to the asynchronous base station A through the reverse dedicated channel. Then, the async base station A analyzes the message on the reverse dedicated channel to determine whether there is a target async base station. If the target async base station is present, the async base station A determines a handoff. Otherwise, the parameters T, T ₀ , and N for detecting the reception strength of the pilot signal from the adjacent synchronization base station are set. Here, T ₀ is a time for detecting the pilot signal of the synchronous base station, T is a section for detecting the pilot signal of the synchronous base station, and N is a parameter that defines the number of times the pilot signal of the synchronous base station is detected. is there. In step 1103, the mobile station B sends an instruction message on the forward dedicated control channel for measuring the reception strength of pilot signals of the asynchronous and synchronous base stations adjacent to the asynchronous base station, and a message including the parameters. To receive. The mobile station B uses the parameters T, T ₀ , and N.
Based on the above, the reception strength of pilot signals from the synchronous and asynchronous base stations adjacent to the asynchronous base station is measured.

In step 1106, the mobile station B detects a pilot signal received from each of the sync base stations adjacent to the async base station A. Here, the pilot signal enables the mobile station B to estimate a channel and rapidly obtain initial synchronization for a new multipath. In addition to detecting the pilot signal, in step 1107, the mobile station B recognizes the synchronization base station C by analyzing a synchronization message received from a synchronization base station such as the synchronization base station C through a forward synchronization channel. Then, the system information for the synchronous base station C is acquired. The synchronization message includes a system ID number, a network ID number, and a pseudo noise offset (pseud
o-noise offset; PN_OFFSET) value, long code information 320 ms, and system information necessary for communication with the synchronous base station C, such as paging channel data rate. For example, the sync channel frame used in the IS-95 system has a length of 80 ms and a data rate of 96 bits. Then, three subframes having a length of one short code period are configured. Here, the synchronization message including the system information for the synchronization base station C includes a message length field (message length field) and a CRC (Cyclic Redundancy Check) 200.
It has a length of at least one bit. Even if the length of the message is 96 bits or less, the 80 ms synchronization frame must add 96 bits to the message to transmit 96 bits. Therefore, the mobile station B receives at least three 80m packets to receive all synchronization messages including the system information.
s sync frames should be received. If the synchronization message is error-free, the mobile station B needs at least 240 ms to recognize the synchronization base station C and receive the information of the synchronization base station C.

In step 1104, the mobile station B sends a message including the measurement result of the reception strength of the pilot signal received from the neighboring base station and the information about the synchronization message to the asynchronous base station A through the reverse dedicated channel. To transmit.

Then, the asynchronous base station A analyzes the message received through the reverse dedicated channel and transmits the measurement result to the upper network. The upper network determines the target synchronous base station C with reference to the measurement result, and transmits a handoff instruction message including information necessary for handoff to the asynchronous base station A. In step 1105, the mobile station B receives a handoff instruction message including traffic channel information for communication with the target synchronous base station C from the asynchronous base station A through a forward dedicated channel. When the handoff instruction message is received, the mobile station B refers to the traffic channel information included in the message and prepares to receive the traffic data from the synchronous base station C. In step 1108, the mobile station B sends null traffic data (null traffic) on the forward basic channel from the synchronous base station C.
fic data) or similar data to verify channel stability. In step 1109, the mobile station B receives a traffic message from the synchronization base station C through the forward basic channel while moving to the cell of the target synchronization base station C. As a result, the call service from the asynchronous base station A is switched to the synchronous base station C. Then, in step 1110, the mobile station B transmits a preamble through the reverse fundamental channel to indicate that it is normally transmitted, and in step 1111 the handoff complete message through the reverse fundamental channel. ) Is transmitted to the synchronous base station C.

As described above, in the conventional forward channel structure of the synchronous mobile communication system, the mobile station B has to receive at least three synchronization frames through the forward synchronization channel of the synchronous mobile communication system. For example, a synchronous mobile communication system having a channel structure as shown in FIG. 2 has a minimum reception time of 240 ms. Therefore, the mobile station B moves from the cell of the asynchronous base station A to the cell of the target synchronization base station C, and at least 240 ms in order to acquire system information for communication with the synchronization base station C. Need time. During the reception time, the mobile station disconnects from the asynchronous base station A. That is, if the procedure of FIG. 3 is performed for a long time, it may cause harmful effects such as loss of data communicated between the async base station and the mobile station.

[0013]

[Problems to be Solved by the Invention]

Therefore, it is an object of the present invention to provide a base station communication apparatus and method in a synchronous mobile communication system having a forward short sync channel for generating a PN_OFFSET signal. Another object of the present invention is to provide a channel transmission apparatus and method for generating a PN_OFFSET signal in a synchronous system. Another object of the present invention is to provide PN_ in a synchronous mobile communication system when a mobile station moves from a cell of an asynchronous mobile communication system to a cell of a synchronous mobile communication system.
It is an object of the present invention to provide a handoff device and process using a forward short sync channel for generating an OFFSET signal.

Still another object of the present invention is to provide PN_OFFS in a synchronous mobile communication system.
An apparatus and method for reducing the time required for a mobile station currently communicating with an asynchronous mobile communication system to receive information of the synchronous mobile communication system by using a forward short sync channel for generating an ET signal. To do.

[0015]

[Means for Solving the Problems]

In order to achieve the above object, the present invention provides a method for performing handoff when a mobile station moves from a cell of an async base station with which a mobile station is communicating to a cell of a synchronous base station, wherein Receiving a PN_OFFSET signal indicating the specific PN_OFFSET value assigned to the synchronous base station from the synchronous base station during the time of, and the mobile station reporting the PN_OFFSET value to the asynchronous base station, The mobile station receiving system information for the synchronous base station from the asynchronized base station; the mobile station performing a handoff to the cell of the synchronous base station based on the received system information; It is characterized by including.

[0016]

DETAILED DESCRIPTION OF THE INVENTION

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings.
In the drawings, the same reference numerals and numbers are commonly used for the same components and parts as much as possible. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may obscure the subject matter of the present invention.

As an example, in order to help a more general understanding of the present invention, such as the length of the frame transmitted on each channel, the coding rate, and the number of data and symbols output from the block of each channel. Such specific details are shown. It is understood that various changes and modifications can be carried out by a person having ordinary knowledge in the technical field.
It will be obvious.

As used herein, the term “PN_OFFSET value” means a message transmitted on the short synchronization channel of the synchronization base station, and the message transmitted on the short synchronization channel is used in the synchronous mobile communication system. The offset value of the pseudo noise code used is shown.

FIG. 1 is a block diagram of a code division multiple access (CDMA) communication system, which is one of the synchronous mobile communication systems according to an embodiment of the present invention, in which each channel is transmitted and received between a mobile station and a base station. Also, a configuration example of a channel communication device for each of these channels is shown. In FIG. 1, each channel is described centering on the transmitter.

To explain the channel configuration of the base station, the controller 101 controls (enables / disables) the operation of each channel generator. Base station physical hierarchy
processes messages sent to and received from an al layer) and communicates messages with upper layers. The pilot channel generator 103, the sync channel generator 104, the short sync channel generator 105, and the paging channel generator 106 are devices that generate common channel information shared by users in a single cell or multiple cells. . The dedicated control channel generator 102, the basic channel generator 107, and the additional channel generator 108 are devices that generate dedicated channel information assigned differently for each user.

The dedicated control channel generator 102 is a forward dedicated control channel (Dedicat).
It processes various control messages received on the ed control channel (DCCH) and transmits them to the mobile station. The message on the forward dedicated control channel is
Radio link protocol (RLP) frames or various control messages (L3 signaling messages) used in IS-95B and medium access control related to packet data service control, eg allocating or deallocating additional channels. (MAC) message. The power control signal is transmitted on a dedicated control channel instead of the basic channel. In this case, the power control signal is included in the control message. Through the forward dedicated control channel, the dedicated control channel generator 102 consults with the base station about the data rate used for the additional channel, or changes the orthogonal code if the orthogonal code is used for the additional channel. To order. The forward dedicated control channel includes a pilot channel generator 103, a synchronization channel generator 104,
The short sync channel generator 105 or the paging channel generator 106 is spread with an unused one of the orthogonal codes that is not assigned. R
The LP frame provides a service capable of normally transmitting an octet stream. The RLP is a transparent RLP.
) And non-transparent RLP. The transparent RLP does not retransmit an erroneously transmitted frame, but informs upper layers of the time and position of the erroneously transmitted frame. The non-transparent RLP includes error correction.

The pilot channel generator 103 processes the information received through the forward pilot channel and transmits the received information to the mobile station. The forward pilot channel is always a logical signal 0 or 1 (all 0's or 1 ').
s) is transmitted. Here, it is assumed that the pilot channel transmits a logical signal "0". The pilot channel signal is used by the mobile station for initial synchronization and channel estimation for a new multipath.
action). The pilot channel is spread with one specific orthogonal code assigned in advance.

The sync channel generator 104 processes the information received through the forward sync channel and transmits the received information to the mobile station. Information transmitted through the synchronization channel is transmitted to all mobile stations in one cell at an initial time (ini
tial time) and frame synchronization. The forward synchronization channel is spread with a specific pre-allocated Walsh code.

The short sync channel generator 105 processes the information received through the short sync channel and transmits the received information to the mobile station. The information on the short sync channel, which has a length of K bits, is provided to the mobile station to retrieve the information for the sync base station in a short time. The information represented by the value is the PN_ of the synchronous base station.
It can be an OFFSET value and a zero padding bit. Since the mobile station acquires the information within a short time, the information is transmitted a predetermined number of times N ₂ within the period of one PN short code. Examples of K and N ₂ are shown in FIGS. 5 and 6. The mobile station communicating with the asynchronous mobile communication system receives the information and transmits the information to the asynchronous base station within one PN short code period. Therefore, the information is transmitted so that the asynchronized base station can update the information for neighboring cells of the base station. Also, the information is used for a handoff that occurs when the mobile station moves from a cell of the asynchronous mobile communication system to a cell of the synchronous mobile communication system. In addition to the information, information on the synchronous base station transmitted on the synchronous channel is transmitted to the mobile station by the asynchronous base station through a paging channel or a broadcast channel. When receiving the information on the short sync channel, it already knows the system information of the sync base station,
The mobile station moving to the cell of the synchronized base station can communicate with the synchronized base station without a separate synchronization process.

The information on the short sync channel is spread with one specific Walsh code pre-allocated to the short sync channel and used equally in all systems. The paging channel generator 106 processes information received on a forward paging channel and transmits the received information to the mobile station. The information on the paging channel is all the information needed before setting up the traffic channel. The forward paging channel is spread with one pre-assigned orthogonal code.

The fundamental channel generator 107 processes information received through a forward fundamental channel and transmits the received information to the mobile station. The information on the forward basic channel may include various control messages (L3 signaling) and power control signals used in IS-95B, in addition to the voice signal. If desired, such information can also include RLP frames and MAC messages. The basic channel has a data rate of 9.6 kbps or 14.4 kbps, and depending on the situation, only ½ of the given data rate, 4.8 kbps or 7
It has a variable data rate such as .2 kbps, 2.4 kbps or 3.6 kbps, which is only 1/4 of the data rate, or 1.2 kbps or 1.8 kbps, which is only 1/8 of the data rate. Such variable data rates have to be detected by the receiving device. The forward fundamental channel is the pilot channel generator 103.
, The sync channel generator 104, the short sync channel generator 105, or the paging channel generator 106 is spread with an orthogonal code.

The additional channel generator 108 processes the information received through the forward additional channel and transmits the received information to the mobile station. The information on the forward additional channel includes an RLP frame, packet data and the like. The additional channel generator 108 has a data rate of 9.6 kbps or higher. The additional channel generator 108 has a pre- promised data rate. For example, the base station communicates with the mobile station through a dedicated control channel at a data rate determined in consultation with the mobile station. The forward supplemental channel is spread with an orthogonal code that is not assigned to the pilot channel generator 103, the synchronization channel generator 104, the short synchronization channel generator 105, or the paging channel generator 106. The basic channel and the additional channel become traffic channels.

The adder 109 is a dedicated control channel generator 102, a basic channel generator 1
07 and the forward link in-phase channel transmission signal from the additional channel generator 108 is added to the transmission signals from the pilot channel generator 103, the synchronization channel generator 104, the short synchronization channel generator 105, and the paging channel generator 106. To do. The adder 110 adds together with the quadrature phase channel transmission signals output from the dedicated control channel generator 102, the basic channel generator 107, and the additional channel generator 108. The spread modulator 111 includes the adder 109.
And 110, multiply the spreading signal by a spreading sequence to up-convert the transmission signal in frequency. The receiver 122 frequency-converts each channel signal of the mobile station in the baseband through the reverse link. Then, the spread signal is multiplied by the converted signal to despread the signal. The structure of the reverse link channel receiver provided to the base station is omitted in FIG.

To explain the channel configuration of the mobile station, the controller 113 enables / disables the operation of each channel generator, processes the message communicated by the mobile station, and communicates the message with upper layers. To do. The dedicated control channel generator 114 processes various control messages received through the reverse dedicated control channel and transmits them to the base station. The message on the reverse dedicated control channel is a Radio Link Protocol (RLP) frame or I
It includes various control messages used in S-95B and medium access control messages (MAC) related to packet data service control, eg, allocating or deallocating additional channels. In the case of the reverse link, the power control signal is inserted in the pilot channel for transmission and is not separately transmitted through the dedicated control channel. Through the reverse dedicated control channel, the dedicated control channel generator 114 consults with the base station about the data rate used for the additional channel. The reverse dedicated control channel generator 114 spreads each channel with a unique orthogonal code pre-assigned to each channel, distinguishes individual channels, and uses a unique PN code to distinguish users from the signal from the user. To spread. Therefore, different orthogonal codes are assigned to dedicated control channels, pilot channels, access channels, basic channels, and additional channels to distinguish each channel, and each orthogonal code used for all channels is shared by all users. To do. For example, the orthogonal code used for the dedicated control channel is shared by all users to distinguish the dedicated control channel.

The reverse dedicated control channel has a fixed data rate of 9.6 kbps, prevents performance degradation due to data rate determination, and eliminates the need for a data rate determination circuit. Therefore, the complexity of the receiver is reduced. Also, the reverse dedicated control channel has the same data rate such as 9.6 kbps which is the basic data rate of the voice signal, thereby maintaining the same service diameter as the basic voice service.

The pilot channel generator 115 processes the information received through the reverse pilot channel and transmits the received information to the base station. Like the forward pilot channel, the reverse pilot channel enables fast acquisition of initial synchronization and channel estimation for new multipaths. Also, the reverse pilot channel transmits reverse power control information by adding a power control signal to the pilot signal at a limited time.

The access channel generator 116 processes the information received through the reverse access channel and transmits the received information to the base station. The information on the access channel includes all information of the mobile station required by the base station before the setting of the control message and the traffic channel.

The fundamental channel generator 117 processes information received through the reverse fundamental channel and transmits the received information to the base station. The information on the reverse fundamental channel normally includes a voice signal. Such information may include various control messages (L3 signaling) used in IS-95B in addition to the voice signal. If required, the information can also include RLP frames and MAC messages. In the case of the reverse link, the power control signal is inserted in the pilot channel for transmission and is not separately transmitted through the access channel. The fundamental channel has a fixed data rate of 9.6 kbps or 14.4 kbps, and depending on the situation, only 1/2 of the given data rate 4.
8kbps or 7.2kbps, only 1/4 of the data rate 2.4kbps or 3.6kbps
, Or having a variable data rate such as 1.2 kbps or 1.8 kbps, which is only 1/8 of the data rate. Such a variable data rate has to be detected by the receiving device. The reverse fundamental channel generator 117 spreads each channel with a unique orthogonal code pre-assigned to each channel, distinguishes each channel, and outputs a signal from the user with a unique PN code that distinguishes the user. Spread. Therefore, different orthogonal codes are assigned to the pilot channel, access channel, basic channel, and additional channel to distinguish each channel, and each orthogonal code used for all channels is shared by all users. For example, the orthogonal code used for the fundamental channel is shared by all users to distinguish the fundamental channel.

The supplemental channel generator 118 processes the information received through the reverse supplemental channel and transmits the received information to the base station. The information on the reverse additional channel includes an RLP frame, packet data and the like. The additional channel generator 118 has a data rate of 9.6 kbps or higher. The additional channel generator 118 has a pre- promised data rate. For example, the base station communicates with the mobile station through a dedicated control channel at a predetermined data rate in consultation with the mobile station. The reverse additional channel spreads each channel with a unique orthogonal code pre-assigned to each channel, distinguishes individual channels, and spreads a signal from a user with a unique PN code that distinguishes users. The basic channel and the additional channel become traffic channels.

The adder 119 adds together the transmission signals on the reverse link received from the dedicated control channel generator 114 and the pilot channel generator 115. The adder 120 includes an access channel generator 116 and a basic channel generator 1
17 and the transmission signals on the reverse link received from the additional channel generator 118 are added together. The spread modulator 121 multiplies the transmission signals from the adders 119 and 120 by a spreading sequence, and up-converts the transmission signal in frequency. The receiver 112 frequency-converts each channel signal of the mobile station on the reverse link in the baseband. Then, the spread signal is multiplied by the converted signal to despread the signal. The configuration of the reverse link channel receiver provided to the base station comprises:
It is omitted in FIG.

As shown in FIG. 1, in the CDMA communication system according to the embodiment of the present invention,
The base station includes a controller 101, a dedicated control channel generator 102, a pilot channel generator 103, a synchronization channel generator 104, a short synchronization channel generator 105, a paging channel generator 106, a basic channel generator 107, and an additional channel. It consists of a generator 108. Then, the mobile station controls the controller 113.
, A dedicated control channel generator 114, a pilot channel generator 115, an access channel generator 116, a basic channel generator 117, and an additional channel generator 118. The signals from the dedicated control channel generator 102, the basic channel generator 107, and the additional channel generator 108 are, for example, in-phase channel components (in-ph) for the output forms of the individual channel generators in the base station.
ase channel component and quadrature-phase channel
l component) two-channel signal. However, only one channel signal is generated from the pilot channel generator 103, the sync channel generator 104, the short sync channel generator 105, and the paging channel generator 106. Here, it is assumed that the only channel component is the in-phase channel component.

Unlike the channel generator of the base station, the channel generator of the mobile station generates only one channel component. Therefore, the outputs of the dedicated control channel generator 114 and the pilot channel generator 115 of the mobile station are added and input to the spread modulator 121 as an in-phase channel, and then the remaining channel generators 116, 117 and 118 are added. The outputs are added and input to the spread modulator 121 as a quadrature channel. When using the accelerator channel, the access channel generator 116 generates an output before the traffic channel is generated, so that the output of the pilot channel generator 115 is an in-phase channel input and the output of the access channel generator 116. Is the quadrature channel input.

The structure and operation of all channel transmitters except the short sync channel transmitter as shown in FIG. 1 are described in Korean Patent Application No. 98- filed by the inventor of the present application.
It is disclosed in detail in 11381. Hereinafter, the detailed configuration of the short sync channel transmitter will be described first, and then,
A procedure for performing a handoff from an asynchronous mobile communication system to a synchronous mobile communication system will be described. FIG. 4 illustrates a detailed configuration of the short sync channel transmitter 105 according to an embodiment of the present invention.

Referring to FIG. 4, the encoder 401 encodes the input short synchronization channel data and outputs the encoded short synchronization channel data. The short sync channel data may be a PN_OFFSET value, and the encoder 401 may be a convolutional encoder or a turbo encoder. In FIG. 4, it is assumed that a convolutional encoder having a code rate of 1/2 and a constraint length of 9 is used.
The interleaver 403 interleaves the symbols output from the repeater 402 to prevent burst errors. The interleaver 403 may be a block interleaver or a turbo interleaver. The signal converter 404 converts the level of the short sync channel signal output from the interleaver 403. The multiplier 405 multiplies the sync channel signal output from the signal converter 404 by an orthogonal code. The orthogonal code used in the multiplier 405 is a predetermined one of Walsh codes. The multiplier 405
The Walsh code used in 1 must be the only specific Walsh code shared by users in a synchronous mobile communication system. The Walsh code used in the multiplier 405 has a length defined in the synchronous mobile communication system. For example,
The Walsh code has a length of 128 in the IMT2000 SR1 environment.
It has a length of 256 in the T2000 SR3 environment. The encoder 401, the repeater 402, and the interleaver 403 are optional rather than required. And those types are also selective. The information input to the short sync channel generator 105 may have various forms. For example, the input of the short sync channel generator 105 is simply a PN_OFFSET value or C
PN_OFFSET value with RC or PN_OFFSET encoded separately
Can be a value.

FIG. 5 shows a frame structure of information input to the short sync channel generator 105. Referring to FIG. 5, K input to the short sync channel generator 105.
The bit data field 501 is the PN_OFFSET value of the synchronous base station.
Here, the K bit represents a PN_OFFSET value. In FIG. 5, the PN_O
The FFSET value and zero padding bit are K bits, and CRC5 is used for transmission.
02 is added. Current synchronous mobile communication systems use a PN_OFFSET value of 9. The length of the information frame input to the short sync channel generator 105, the data rate, and the length of the CRC are changed according to the length of the Walsh code, the number of repetitions, and the type of the encoder.

FIG. 6 shows the structure of a short sync channel frame transmitted within one cycle of a PN single code (eg, 26.6 ... ms). Referring to FIG. 6, the short synchronization channel frame is transmitted N ₂ (N ₂ ≧ 1) times within one cycle of the PN single code. That is, PN
The _OFFSET value can be transmitted several times within one cycle of the PN single code. Therefore, the mobile station can acquire information about the synchronous base station within a short time. The number of transmissions N ₂ of the short synchronization channel frame is calculated according to the following formula.

[Formula 1] N_chip = {(K + CRC) × R × N ₁ × W ¹ } × N ₂

The variables used in [Equation 1] are defined as follows. N_chip is the number of chips in one cycle of the PN short code (for example, 32 in the case of SR1).
98304) for 768 or SR3). K is a data bit (PN_OFFSET value + zero padding bit length). CRC is the CRC bit used in the short sync channel. R is the code rate of the encoder used in the short sync channel generator. N ₁ is the number of symbol repetitions. W ¹ is the length of the Walsh code. N ₂ is the number of transmissions of the PN_OFFSET frame within one cycle of the PN short code.

For example, in the current synchronous mobile communication system, if PN_OFFSET value = 9 bits, N_chip = 32768, R = 2, N ₁ = 2, and W ¹ = 128, then [
[Equation 1] can be re-recorded as 64 = {(K + CRC) × N _{2 and} the bit rate of the short sync channel is 2400 bps. In order to repeat a short sync channel frame twice, K + CRC must be 32 bits. If the CRC has 20 bits, K can be set as 10 bits including 9 bits of the PN_OFFSET value and zero padding bit 1.

As another example, in the current synchronous mobile communication system, PN_OFFSET value =
Assuming 9 bits, N_chip = 32768, R = 2, N ₁ = 2, and W ¹ = 128, [Equation 1] can be recorded again as 64 = {(K + CRC) × N ₂ , The bit rate of the sync channel is 2400 bps. In order to repeat the short sync channel frame four times, K + CRC must be 16 bits. If the CRC has 4 bits, K can be set as 12 bits including 9 bits of PN_OFFSET value and zero padding bit 3.

A procedure for performing a handoff from an asynchronous mobile communication system to a synchronous mobile communication system according to an embodiment of the present invention will be described. In the following description, the base station of the synchronous mobile communication system is referred to as “synchronous base station”, and the base station of the asynchronous mobile communication system is referred to as “asynchronous base station”.

In FIGS. 7 to 9, the handoff between the asynchronous base station and the synchronous base station is a soft handoff. Also, the synchronous base station has a channel structure as shown in FIG. FIG. 7 shows a handoff procedure of the asynchronous base station A according to the embodiment of the present invention.

Referring to FIG. 7, in step 701, the asynchronous base station A receives the measurement result of the pilot signal of the adjacent asynchronous base station from the mobile station B. In order to search for a target async base station, the mobile station B measures the strength of a pilot signal received from the async base station adjacent to the async base station A, and outputs the async signal having a pilot signal equal to or greater than a reference value. Report information to the base station. Then, in step 702, the asynchronous base station A determines whether there is a target of the asynchronous base station to be handed off based on the measurement result received from the mobile station B.
If there is such an async base station, in step 703, the async base station A sends a handoff instruction message including information necessary for handoff to the mobile station B.
Transmit to. Otherwise, the async base station A proceeds to step 704 and sets parameters T, T ₀ and N for detecting a pilot signal of an adjacent sync base station. Such parameters T, T ₀ , and N are shown in FIG. T ₀ is a time for detecting the pilot signal of the synchronous base station, T is a section for detecting the pilot signal of the synchronous base station, and N is a parameter defining the number of times for detecting the pilot signal of the synchronous base station.

In step 705, the async base station A sends the parameter and an instruction message for measuring the pilot signal strength of the async base station A and a sync base station adjacent to the async base station A to the mobile station B. Transmit to. The mobile station B detects the pilot signal of the adjacent synchronization base station during the period T ₀ . The mobile station B maintains communication with the asynchronized base station A for the period T-T ₀ , and
The pilot signal of the asynchronized base station adjacent to is detected. Then step 7
At 06, the asynchronous base station A receives the measurement result of the pilot signal from the mobile station B. The measurement result of the pilot signal is divided into four types.
1) Information for successful detection of another target synchronization base station, (2) Information for successful detection of the target synchronization base station, (3) Success of the target synchronization base station and other target asynchronization base stations Information on the above-mentioned detection, and (4) information on the detection that the target base station has failed. Information about the successful detection of the sync base station is transmitted together with the system information of the sync base station C. There are two types of system information of the synchronous base station C. One is the PN_OFFSET value of the detected sync base station C having the short sync channel shown in FIG. 1, and the other is the detected sync base station received on the sync channel (FIG. 2). Is a synchronization message of.

Upon receiving the measurement result of the pilot signal from the mobile station B, in step 707, the async base station A determines whether there is a target cell to be handed off. If there is no target cell, the async base station A returns to step 701 and repeats the above procedure. On the other hand, if the target cell is detected, in step 708, the async base station A determines whether the target cell is an async base station or a sync base station. That is, since the mobile station measures all the pilot signals of the asynchronous base station and the synchronous base station in step 704 of determining the parameters, the asynchronous base station A determines that the detected target cell is the synchronous base station in step 708. , Or an async base station.

When all of the synchronous base station and the asynchronous base station are detected, the system parameter of the asynchronous base station A is used to determine the base station to handoff, and the system information of the asynchronous base station is Used to determine if a base station has priority over anything else. When the target cell is determined to be the async base station in step 708, the async base station A transmits to the mobile station B a handoff instruction message necessary for handoff to the async base station thus determined. On the other hand, if the target cell is determined to be the synchronous base station, step 70.
In step 6, the asynchronous base station A transmits the pilot signal strength and PN_OFFSET value of the determined synchronous base station received from the mobile station B, or system information to the upper network.

As a result, in step 710, the asynchronous base station A receives the handoff request message from the upper network. When handed off to the synchronous mobile communication system shown in FIG. 1, the asynchronous base station A further receives system information for the synchronous base station. During step 710, the upper network transmits information indicating that the mobile station will be handed off to the target synchronization base station. The receiving target of such information can be the synchronous base station or its superordinate network. Upon receiving the handoff instruction message from the upper network, the async base station A transmits to the mobile station B a handoff instruction message including information necessary for handoff to the determined synchronous base station.

In another embodiment, the synchronous base station A skips step 704 and performs step 707 immediately after the mobile station B moves to the cell of the asynchronous base station A. Therefore, such an embodiment has the advantage that the time for the async base station to hand off the mobile station is reduced. 8A and 8B show a handoff procedure of a mobile station communicating with an async base station according to an embodiment of the present invention. The mobile station operates in a dual mode, which enables communication between an asynchronous base station and a synchronous base station.

Referring to FIG. 8A, in step 801, the mobile station B measures the strength of the received pilot signal and transmits the measurement result to the asynchronous base station A. Here, when the mobile station finds another target async base station, it transmits a message indicating that another target async base station is found. Otherwise, it sends a message indicating that no other target async base station was found. Then, in step 802, the mobile station B determines whether a request message requesting to measure a pilot signal of a base station adjacent to the async base station A is received from the async base station A. In response to the message requesting the measurement of the pilot signal, when the handoff instruction message to the target cell of the async base station (from the async base station A in step 703 of FIG. 7) is received, the mobile station B in step 803. Performs a handoff to the cell of the async base station A, and transmits a preamble signal on the reverse link to a target cell of the async base station in step 804. As a result, in step 805, the mobile station B transmits a handoff completion message to the target cell of the async base station.

On the other hand, if the message received in step 802 is a message requesting measurement of a pilot signal (transmitted in step 705 of FIG. 7), in step 806 the mobile station B determines Receives parameters for determining pilot signals for asynchronous and synchronous base stations adjacent to station A. The parameters are defined in FIG. In step 806, when setting the parameters, if the time T ₀ for detecting the pilot signal of the target synchronization base station is too long, the communication with the asynchronous base station becomes unstable. If the section T is too long, it may be difficult to detect the pilot signal of the synchronous base station, and if the parameter N is large, the time for detecting the target base station (for example, the target base station or the target asynchronous base station) is significantly long. As a result, the mobile station may miss the time to perform the handoff, and the call service may be interrupted. Therefore, the parameters must be set in consideration of such points.

In steps 807 to 813, during the period T ₀ , the mobile station B detects the section T by N times the strength of the pilot signal of the synchronous base station. During the cycle T-T ₀ , the mobile station B detects the pilot signal strength of the asynchronous base station adjacent to the synchronous base station A while maintaining communication with the asynchronous base station A in step 810. In step 808, the pilot signal of the synchronous base station is detected by two methods. One is a method of directly detecting the synchronization signal during the cycle T ₀ , and the other is a method of reducing the cycle T _{0 in} order to guarantee the stability of the communication between the asynchronous base station and the mobile station. The signal transmitted from the synchronous base station is stored in the buffer by setting the value, and the pilot signal of the synchronous base station is stored in the buffer in the off-line method during the period T-T _0. This is the method of detection. When the pilot signal of the synchronous base station is detected in step 808, the mobile station B interprets the system information of the synchronous base station from the message of the synchronous channel or the short synchronous channel of the synchronous base station in step 809. To do. In step 809, using the method of directly detecting the pilot signal during the period T _0, the mobile station B communicates with the synchronization base station for a period sufficient to acquire the system information of the synchronization base station. You have to keep the channel. And it does not return to the channel with the asynchronous base station. Using the method of detecting the pilot signal of the synchronization base station from the signal stored in the buffer in step 809, the mobile station stores the pilot signal of the synchronization base station in the next period T ₀ after T _{0. During 0} , the channel with the synchronization base station must be held for a period sufficient to acquire the system information of the synchronization base station.

On the other hand, if the sync base station does not have a short sync channel, in step 809, the mobile station B should receive the sync message transmitted to the sync channel of the sync base station for at least 240 ms. Therefore, in order to obtain information necessary for handoff in a mobile communication system having no short sync channel, the stability of communication between the mobile station and the async base station cannot be guaranteed. On the other hand, if the sync base station has a short sync channel as in the sync mobile communication system shown in FIG. 1, in step 809, the mobile station B sends the sync transmitted on the short sync channel within 26.6 ms. Receive the PN_OFFSET value of the base station. Step 8
If the pilot signal is not detected at time T ₀ at 10, the mobile station B detects the pilot signal strength of the async base station adjacent to the async base station A, and the period T
-Keep communication with asynchronous base station for T ₀ . In step 811, the mobile station B determines whether or not the measured pilot signal strength of each asymmetric base station is a value requiring handoff. If such a pilot signal is detected, the mobile station B proceeds to step 813 of FIG. 8B, while the mobile station B proceeds to step 812. If the synchronous base station pilot signal and the asynchronous base station pilot signal to be handed off cannot be detected, the mobile station B is detected in step 812.
Determines whether the number of iterations exceeds N. If the number of iterations does not exceed N and the pilot signal of the synchronous base station or the pilot signal of the asynchronous base station is not detected, the mobile station B returns to step 807 and steps 808 to 81.
Repeat 0. If the number of iterations exceeds N, in step 812, the mobile station B
Transmits the measurement results obtained up to that point to the asynchronous base station. The mobile station B proceeds to step 813 immediately after step 809 if the pilot signal is detected in the number of repetitions not exceeding N in step 808. In step 810, if the pilot signal is detected for a number of iterations not exceeding N, the mobile station B determines
Immediately proceeding to step 813, in step 811, the detected pilot signal is determined to have an appropriate strength for the target async base station.

After transmitting the measurement result of the pilot signal in step 813 of FIG. 8B, the mobile station B determines in step 814 whether a handoff instruction message is received from the async base station A. When the handoff instruction message is received, the mobile station B returns to step 802. On the other hand, in step 815, the mobile station B determines whether the handoff instruction message is a handoff message to the target synchronous base station or the target asynchronous base station. Step 814
If the handoff indication message received in step 8 is a handoff message to the target async base station, the mobile station B performs steps 819 to 821, which are similar to steps 803 to 805 in FIG. 8A.

On the other hand, when the handoff instruction message is determined as the handoff message to the target synchronization base station in step 815, the mobile station B determines in step 8
Proceed to step 16 to perform a handoff using the system information of the target synchronization base station included in the received handoff instruction message. That is, in step 817, the mobile station B moves to the target synchronization base station, receives the traffic data on the forward basic channel from the synchronization base station, and transmits the preamble on the reverse basic channel to the synchronization base station. Then, in step 818, the mobile station B
Transmits a handoff completion message to the synchronization base station on the reverse fundamental channel.

FIG. 9 illustrates a target sync base station handoff procedure according to an embodiment of the present invention, and it is assumed that the sync base station has the same channel structure as shown in FIG. Referring to FIG. 9, in step 901, the synchronization base station C determines a pilot signal on a pilot channel and PN_ of the synchronization base station C on a short synchronization channel.
Transmit the OFFSET value. The PN_OFFSET value of the synchronous base station C is shown in FIG.
It can be transmitted to the short sync channel as shown in FIG. The short sync channel generator may have a structure as shown in FIG. 4, wherein an encoder, an interleaver, and an iterator are selectively used. The information of the short sync channel is transmitted N ₂ times every 26.6 ms. In step 902, the synchronous base station C receives a handoff message from the higher level network to the synchronous base station of the mobile station. In step 903, the synchronized base station C transmits the null traffic channel data on the forward fundamental channel or data similar thereto to the mobile station B. Here, the step 903
Is selective. In step 904, the synchronized base station C transmits a traffic channel to the mobile station B using the forward basic channel immediately after the mobile station B moves to the cell of the synchronized base station C. Then, in step 905, the synchronous base station C receives the handoff completion message from the mobile station B and ends the handoff.

FIG. 12 shows a handoff procedure from the cell of the asynchronous base station A to the cell of the synchronous base station C according to the embodiment of the present invention. In the following description, it is assumed that the synchronous base station has the same channel structure as shown in FIG. Referring to FIG. 12, in step 1201, the mobile station B determines that the asynchronous base station A
From the base station A through the broadcast channel or the paging channel, the message including information for other base stations adjacent to the asynchronous base station A. In step 1202, the mobile station B measures the reception strength of the pilot signal transmitted from the adjacent base station and transmits a message including the measurement result of the pilot signal to the asynchronous base station A through the reverse dedicated channel. Then, the async base station A analyzes the message on the reverse dedicated channel to check whether there is a target async base station. If there is a target async base station,
The asynchronous base station A determines a handoff. On the other hand, parameters T, T ₀ and N for detecting the reception strength of the pilot signal from the adjacent synchronization base station are set. In step 1203, the mobile station B sends a message including an instruction message and parameters on the forward dedicated control channel to measure the reception strength of the pilot signals of the synchronous and asynchronous base stations adjacent to the asynchronous base station A. To receive. Here, T ₀ is a time for detecting the pilot signal of the synchronous base station, T is a section for detecting the pilot signal of the synchronous base station, and N is a parameter that defines the number of times the pilot signal of the synchronous base station is detected. is there. Upon receiving the message on the forward dedicated control channel, the mobile station B receives pilot signals from the synchronous and asynchronous base stations adjacent to the asynchronous base station A based on the parameters T, T ₀ and N. Measure the strength.

In step 1206, the mobile station B detects the pilot signal of the synchronous base station C having the maximum peak value. Here, the pilot signal enables the mobile station B to estimate a channel and quickly obtain initial synchronization for a new multipath.

In step 1207, upon detecting the pilot signal, the mobile station B analyzes the short sync frame received from the sync base station C on the forward short sync channel to detect PN_OFFSET of the sync base station C. Get the value. Then, the mobile station B transmits a message including the PN_OFFSET value obtained in step 1207 and the measurement result of the reception strength of the pilot signal from the adjacent base station to the asynchronous base station A through the reverse dedicated channel. Then, the asynchronous base station A reports the message received from the mobile station B through the reverse dedicated channel to the upper network. The upper network confirms the target synchronous base station C from the report and transmits a handoff instruction message including information necessary for handoff to the asynchronized base station A. Here, the handoff instruction message includes system information of the target synchronization base station C and information about a traffic channel for communication with the target synchronization base station C. The reason is that the mobile station simply receives the PN_OF of the sync base station C received through the short sync channel.
This is because it is a state having only the FSET value. After that, when the asynchronous base station A receives the handoff instruction message from the upper network, in step 1205, the asynchronous base station A transmits a handoff instruction message including information necessary for handoff to the mobile station B. .

The mobile station B sends a handoff instruction message including information on a traffic channel for communication with the target synchronous base station C from the asynchronous base station A and system information of the synchronous base station C through a forward dedicated channel. To receive. Upon receiving the handoff instruction message, the mobile station B refers to the traffic channel information and the system information included in the message and prepares to receive the traffic data from the synchronous base station C. In step 1208, the mobile station B receives the null traffic data or other data from the synchronous base station C through the forward fundamental channel and confirms channel stability. In step 1209, the mobile station B receives the traffic message from the synchronization base station C through the forward basic channel while moving to the cell of the target synchronization base station C. As a result, the call service from the asynchronous base station A is switched to the synchronous base station C. Then, in step 1210, the mobile station B transmits a preamble through the reverse fundamental channel to indicate that it is normally transmitted, and in step 1211, synchronizes the handoff completion message on the reverse fundamental channel. Transmit to base station C.

The difference between the related conventional method shown in FIG. 11 and the present invention shown in FIG. 12 is the method in which the mobile station B acquires the system information of the asynchronous base station C. In a related conventional method, the mobile station B receives the synchronization signal frame of the synchronization base station C for at least 240 ms and interprets the synchronization signal message included in the synchronization signal frame. Unlike this method, in the method of the present invention, the mobile station B uses the PN_OFFS of the synchronization base station C on a short synchronization channel.
Only the ET value is obtained, the received PN_OFFSET value is reported to the asynchronous base station A, and the system information of the synchronous base station C, which is stored in the asynchronous base station A or received from the upper network, is sequentially displayed. To transmit. The method of the present invention reduces the time required for the mobile station to acquire the system synchronization information of the target synchronization base station, thereby stabilizing the communication with the asynchronization base station. be able to.

Therefore, according to the present invention, the base station in the synchronous mobile communication system transmits the PN_OFFSET value to the mobile station through the short synchronization channel so that the mobile station can acquire the information about the adjacent cell within a short time. To Also, the mobile station currently communicating in the asynchronous mobile communication system can easily perform the handoff to the synchronous mobile communication system using the PN_OFFSET value acquired through the short synchronization channel. That is, the mobile station can acquire information about cells adjacent to the asynchronous mobile communication system within a short time, and thus the call disconnection time between the asynchronous mobile communication system and the mobile station can be shortened.

As described above, the detailed description of the present invention has been made in detail with reference to specific embodiments, but the scope of the present invention should not be limited to the above embodiments, and the scope of the present invention It will be apparent to those of ordinary skill in the art that various modifications can be made therein.

[Brief description of drawings]

FIG. 1 is a diagram illustrating a structure of a base station in a synchronous mobile communication system having a short synchronization channel according to an embodiment of the present invention.

FIG. 2 is a diagram showing a structure of a base station in a synchronous mobile communication system according to a conventional technique.

FIG. 3 is a diagram showing a procedure in which a mobile station currently communicating with an asynchronous mobile communication system receives information for the synchronous mobile communication system.

FIG. 4 illustrates a detailed structure of the forward short sync channel generator shown in FIG.

FIG. 5 is a diagram showing a structure of short sync data input to the short sync channel generator.

FIG. 6 is a diagram illustrating repetitive transmission of a short sync frame within one period of a PN short code on a forward short sync channel.

FIG. 7 is a diagram illustrating a handoff procedure of an async base station according to an embodiment of the present invention.

FIG. 8 illustrates a mobile station handoff procedure according to an embodiment of the present invention.

FIG. 9 is a diagram showing a handoff procedure of a synchronous base station according to the embodiment of the present invention.

FIG. 10 is a diagram showing detection parameters of a base station pilot signal used in an asynchronous base station according to an embodiment of the present invention.

FIG. 11 is a diagram illustrating messages transmitted and received while a mobile station according to the related art performs a handoff from an asynchronous base station to a synchronous base station.

FIG. 12 is a diagram illustrating messages transmitted and received while a mobile station performs a handoff from an async base station to a sync base station in a sync mobile communication system having a short sync channel according to an embodiment of the present invention.

[Explanation of symbols]

  101,113 controller   102,114 Dedicated control channel generator   103,115 Pilot channel generator   104 Sync Channel Generator   105 Short sync channel generator   106 paging channel generator   107,117 Basic channel generator   108, 118 Additional channel generator   109,119,120 adder   111,121 Spread modulator   112,122 receiver   116 Access channel generator   401 encoder   402 iterator   403 Interleaver   404 Signal converter   405 multiplier   501 Kbit data field   502 CRC

─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Seung-Joe Maen             Republic of Korea, Kyong Gide, 463-070, Song             Nam-si Puntan-gu-ya-tap             Maehwa Maeul 201-1001 (72) Inventor Jamen Ann             Korea, Seoul, 135-239, Gangnam-             Gu Il Won Pong-Don (no street number)             Pleasant Ho Apt # 109-             303 (72) Inventor Yusk Yun             Korea, Seoul, 135-280, Gangnam-             Gu Taech-dong 954-21 F term (reference) 5K067 AA14 DD25 EE02 EE10 JJ35                       JJ39

Claims (14)

[Claims] 1. A forward pilot channel generator for generating a pilot signal, a forward synchronization channel generator for generating a synchronization signal, and a forward short synchronization for generating a short synchronization signal including a pseudo noise offset value of a base station. A channel generator, a forward dedicated control channel generator that generates a dedicated channel control message, a forward dedicated basic channel generator that generates a voice signal, and a forward dedicated additional channel generator that generates packet data, A base station transmitter comprising: 2. The short sync channel generator includes an encoder that encodes the pseudo noise offset value, an iterator that repeats symbols from the encoder for a predetermined number of times, and an output from the iterator. An interleaver that interleaves, a signal converter that level-converts the output from the interleaver, and a multiplier that orthogonally spreads the output of the signal converter by multiplying the output of the signal converter by a specific orthogonal code. The base station transmitter according to claim 1, comprising: 3. The base station transmitter according to claim 1, wherein the short sync signal from the short sync channel generator is repeated at least once within a period of the pseudo noise short code. 4. The base station transmitter according to claim 2, wherein the encoder encodes data forming a pseudo noise offset value added to a cyclic redundancy check (CRC) code. 5. A method for performing a handoff from the asynchronous base station to the synchronous base station when the mobile station moves from a cell of the asynchronous base station with which the mobile station is communicating to a cell of the synchronous base station, wherein: Receiving a pseudo noise offset signal indicating a specific pseudo noise offset value assigned to the synchronous base station from the synchronous base station for a predetermined time, and reporting the pseudo noise offset value to the asynchronous base station. A step of receiving system information for the synchronous base station from the asynchronous base station, and performing a handoff to the synchronous base station based on the received system information. Method. 6. The method of claim 5, wherein the pseudo noise offset signal is broadcast over a forward short sync channel of the sync base station. 7. The method of claim 6, wherein the pseudo noise offset signal is transmitted at least once within a period of the pseudo noise short code. 8. A method of performing a handoff from the asynchronous base station to the synchronous base station when the mobile station moves from the cell of the asynchronous base station with which the mobile station is communicating to the cell of the synchronous base station. A step of transmitting a message requesting a search for an adjacent synchronization base station to the mobile station, receiving a specific pseudo noise offset value assigned to each synchronization base station from the mobile station, the pseudo noise offset value A step of reporting to a higher level network, a step of receiving system information for the target synchronization base station from the higher level network, and a step of transmitting a handoff instruction message including the received system information to the mobile station, How to characterize. 9. The step of transmitting a request message to the mobile station includes the step of setting parameters relating to a search interval, a search cycle, and a search frequency for the mobile station to search for the adjacent synchronization base station, and the parameter. Transmitting a message to the mobile station. 10. A method of performing a handoff from the asynchronous base station to the synchronous base station when the mobile station moves from a cell of the asynchronous base station with which the mobile station is communicating to a cell of the synchronous base station, the mobile station comprising: Periodically detecting a pilot signal of a synchronous base station adjacent to the asynchronous base station for a predetermined period, and when a pilot signal having a peak value from the synchronous base station is detected for a limited time Receiving a short sync channel signal representing a specific pseudo noise offset value assigned to the sync base station from the sync base station; reporting the pseudo noise offset value to the async base station; Receiving a handoff indication message including system information of the synchronized base station from a base station; and the received system. Wherein and performing a handoff of the to the synchronous base station based on broadcast, that it consists. 11. The step of performing the handoff, referring to traffic channel information included in the system information, receiving null traffic data from the synchronous base station through a traffic channel, and the null traffic data. 11. The method of claim 10, comprising transmitting a preamble signal over a reverse fundamental channel and then transmitting a handoff completion message to the target synchronization base station when it is determined that is successfully received. 12. The mobile station temporarily stores a signal from an adjacent synchronization base station for the predetermined period, and detects the pilot signal of the adjacent synchronization base station from the stored signal. The method described. 13. A method of performing a handoff from the asynchronous base station to the synchronous base station when the mobile station moves from a cell of the asynchronous base station with which the mobile station is communicating to a cell of the synchronous base station. Transmitting to the mobile station a message requesting a search for an adjacent synchronization base station, and the mobile station periodically searching for the adjacent synchronization base station for a predetermined period in response to a request from the asynchronous base station. And, while searching for the adjacent synchronization base station, receives a short synchronization channel signal representing a specific pseudo noise offset value assigned to the synchronization base station from a target synchronization base station, and outputs the pseudo noise offset value to the asynchronous base. Reporting to the upper network, the asynchronous base station reporting the pseudo noise offset value
Receiving system information for the synchronous base station from the upper network, transmitting a handoff instruction message including the system information to the mobile station, the mobile station based on the received system information, the synchronous base Performing a handoff to the station, the method comprising: 14. The method according to claim 13, wherein the request message includes parameters relating to a search period in which the mobile station searches for the adjacent synchronization base station, a search cycle, and a search count.