KR20050000201A - Method and apparatus for effective cancellation of adjacent cell ue interference on base station receiver in td-cdma mobile communication system - Google Patents

Abstract

PURPOSE: An apparatus and method for removing an interfering signal in a TD-CDMA mobile communication system are provided to enable a base station of an adjacent cell to accurately detect an interference component among overall reception signals and remove it to thereby accurately estimate data received from a mobile terminal in its own cell. CONSTITUTION: When a measurement control message is transferred from an RNC(Radio Network Controller)(701) to a UE(User Equipment)(704) through a reference base station(Node B1)(702), the UE(704) checks whether a signal transmitted by the UE(704) works as a major interference component of a neighbor base station(Node B2)(703) and transmits a report on the corresponding measurement to the RNC(701). Upon receiving the measurement report, the RNC(701) transmits a reception command to the neighbor base station(Node B2)(703). The neighbor base station(Node B2)(703) measures an interference component according to reception signals received from UEs positioned in other base stations including the reference base station(Node B1)(702) and removes the interference component from every received signal component.

Description

Apparatus and Method for Eliminating Interference Signals in Time Division-Code Division Multiple Access Mobile Communication System

The present invention relates to an apparatus and method for removing interference signals from a base station receiver in a time division code division multiple access mobile communication system, and more particularly, to an apparatus and method for removing interference signals from an adjacent base station.

Typically, second generation mobile communication schemes that provide voice-oriented services include Global System for Mobile Communications (GSM), Interim Standard (IS) -95, and the like. The GSM was commercialized mainly in Europe in 1992, and provides a service using a time division multiple access (hereinafter, referred to as "TDMA") scheme. Meanwhile, the IS-95 has been commercialized mainly in Korea and the United States, and uses a code division multiple access (hereinafter, referred to as "CDMA") method.

The third generation mobile communication method developed from the second generation mobile communication method refers to a mobile communication method supporting packet service as well as voice service, and uses a CDMA method. The third-generation mobile communication scheme, the European and Japanese type standard method that is based on the asynchronous between base stations 3GPP (3 ^rd Generation Project Partnership, or UMTS) US-standard way and the synchronization based on the between the base stations of 3GPP2 (3 ^rd Generation Project Partnership 2, or CDMA2000). In 3GPP, frequency division duplexing (Frequency Division Duplexing), which distinguishes up / down transmission and reception by frequency, and time division duplexing, which distinguishes up / down transmission and reception by time, for improving limited channel usage efficiency. (Time Division Duplexing: hereinafter referred to as "TDD") has been proposed. The TDD scheme is a High Chip Rate-TDD (HCR-TDD) scheme using a chip rate of 3.84 Mcps (Lega Chip Per Second), and a LCR-TDD (Low Chip Rate-TDD) using a chip rate of 1.28 Mcps. TDD) method.

1 is a diagram showing a general configuration of a radio access network (hereinafter referred to as "RAN") in a mobile communication system using the LCR-TDD scheme. As shown in FIG. 1, the RAN is a core network (hereinafter referred to as "CN") 101 and a plurality of wireless network controllers (Radio Network Controller, hereinafter referred to as "RNC") connected to the CN 101 by wire. 102, 103 and a plurality of base stations (hereinafter referred to as "Node B") that are wired to the respective RNCs 102, 103 (104, 105, 106). ) And a mobile terminal (User Equipment, hereinafter referred to as "UE") 107 wirelessly connected to the Node B (104). In FIG. 1, only one UE 107 connected to the first Node B 104 is illustrated for convenience of description, but it will be apparent that a plurality of UEs are connected to each Node B.

Each RNC (102, 103) serves to control the Node Bs (104, 105, 106) connected via a wire. The Node Bs 104, 105, and 106 have at least one cell and are connected to the UEs 107 located for each cell through a wireless network. The cell means a service area by the corresponding Node B. The first Node B 104 transmits and receives a signal using the same frequency as the UE 107. Meanwhile, various types of forward and reverse channels may be allocated between the first Node B 104 and the UE 107. The UE 107 transmits user information and higher layer signaling information to the first Node B 104 through a reverse channel. The first Node B 104 transmits user information and higher layer signaling information from the UE 107 to the CN 101 through the first RNC 102. In contrast, user information and higher layer signaling information from the CN 101 are provided to the first Node B 104 via the first RNC 102. The first Node B 104 transmits user information and higher layer signaling information provided from the CN 101 to the UE 107 through the forward channel.

FIG. 2 is a diagram illustrating a radio frame structure in a mobile communication system using a conventional LCR-TDD scheme. FIG. 3 is a tile slot and a downlink pilot time slot shown in FIG. The following diagrams show the structures of "DwPTS" and uplink link time slots (hereinafter referred to as "UwPTS").

Referring to FIG. 2, one radio frame 201 has two sub-frames having a length of 10800 chips (10 ms) and a length of 5 ms according to a chip rate of 1.28 Mcps used in the LCR-TDD scheme. It consists of Two sub-frames constituting the one radio frame 201 have the same structure. The one subframe 202 includes seven timeslots (TS # 0 to TS # 6), a DwPTS 204, an UpPTS 206, and a guard period (hereinafter referred to as "GP") 205. It consists of. Each of the timeslots has a length of 864 chips and is used as an uplink (hereinafter referred to as "UL") time slot or a forward (downlink, referred to as "DL") time slot. The arrow pointing upward in FIG. 2 indicates UL timeslots, and the arrow pointing downward indicates DL timeslots. How many of the seven time slots constituting the one subframe 202 are used as DL timeslots or UL timeslots is set by the ratio of forward / reverse transmission data in the base station. However, the first time slot (TS # 0) 203 of the seven timeslots TS # 0 to TS # 6 constituting the one sub-frame should always be used as the DL timeslot, and the second The timeslot (TS # 1) 207 should always be used as a UL timeslot. Meanwhile, the DwPTS (96 chips) 204, the GP (96 chips) 205, and the UpPTS (160 chips) 206 are present between the TS # 0 203 and the TS # 1 207. The DwPTS 204 is used by the UE to perform initial cell search, synchronization, or channel estimation, and the UpPTS 206 is used by the base station to synchronize channel estimation with backward UE. The GP 205 is configured to perform multiplexing of forward transmission signals transmitted through the TS # 0 203 because adjacent TS # 0 203 and TS # 1 207 are used as DL timeslots and UL timeslots, respectively. The path delay is used to prevent interference caused by the backward transmission signal transmitted through the TS # 1 (207). In the LCR-TDD scheme, two switching points are required in one sub-frame for conversion of forward / reverse transmission. The switching points are at the switching points of the DL timeslot and the UL timeslot. The first switching point 208 of the two switching points is fixed between the DwPTS 204 and the UpPTS 206, and the second switching point 209 is the TS according to the ratio of forward / reverse transmission data. It exists at any position between # 1 and TS # 6.

Meanwhile, a first common control physical channel (hereinafter referred to as "P-CCPCH") is transmitted through two codes through the TS # 0 203. Here, the code serves to distinguish forward channels using the same timeslot or reverse channels using the same timeslot in the LCR-TDD mobile communication system. In general, an orthogonal code having a length of 16 is used as the code. The P-CCPCH is a physical channel for transmitting a broadcast channel (hereinafter, referred to as "BCH") containing system information of a base station.

Referring to FIG. 3, one TS includes two data regions 301 and 303, a midamble region 302, and a GP 304. The data symbols transmitted through each of the data regions 301 and 303 are spread by an orthogonal code for channel division having a spreading factor (hereinafter, referred to as "SF") 16 and have a length of 352 chips. Through the data areas 301 and 303, not only data symbols, but also TFCI (hereinafter referred to as "TFCI") and TPC (Transmit Power Control, referred to as "TPC") as necessary. And symbols such as SS (Synchronization Shift, hereinafter referred to as "SS") are also transmitted. The TFCI plays a role of informing the transmission rate and channel code parameter of the DL channel transmitted from the Node B to the UE. The same is true for the UL channel. The TPC is used to control the DL transmission power of the Node B when transmitted on the UL channel, and is used to control the UL transmission power of the UE when transmitted on the DL channel. The SS is used to transmit a command for adjusting synchronization when the synchronization is out of sync due to a change in distance between the UE and the Node B during transmission. By the command transmitted to the SS, the UE may adjust synchronization in units of 1/8 chips.

The midamble transmitted through the midamble region 302 has a different role depending on the DL timeslot and the UL timeslot. In the case of DL timeslots, the midamble 302 is used by the UE to estimate which channels are transmitted from Node B and what channel environment is with Node B. In the case of the UL timeslot, the midamble 302 is used to estimate which UE is transmitting the channel in Node B and the channel environment between the UE and Node B. In addition, in the reverse link, when a unique midamble is allocated to the UE, the Node B may distinguish the UE by the midamble. The midamble 302 has a length of 144 chips and the number of basic codes is 128. One of them is assigned one per cell. Channels transmitted through the same timeslot in the same cell have one basic code and are used by a cyclic shift method.

The GP 304 has a length of 16 chips, and is a section for distinguishing between a time slot currently being transmitted and a next time slot being transmitted. For example, when a DL transmission timeslot follows a UL transmission timeslot or a UL transmission slot follows a DL transmission slot, it serves to prevent interference with each other.

The DwPTS 204 is transmitted through a downlink pilot channel (hereinafter referred to as "DwPCH"), which is a physical channel, and has a 32-chip GP 311 and a 64-chip SYNC-DL code (Synchronization Down-). link code, hereinafter referred to as " SYNC-DL " The GP 311 forms a GP of 48 chip intervals with the GP 304 of the TS # 0 203, which is caused by the multipath delay between the TS # 0 203 and the DwPTS 204. It serves to eliminate interference. The reason why the 48-chip long section is allocated to the GP is to allow the SYNC-DL code 312 in the DwPTS 204 to play a very important role so that it can be stably received.

The SYNC-DL code 312 is the first signal that the UE finds when it encounters an LCR-TDD mobile communication system. The SYNC-DL code 312 is used for initial cell search and synchronization with a cell. Therefore, when the SYNC-DL code 312 causes interference due to the signals transmitted from the TS # 0 203, the UE cannot perform normal communication with the Node B. There are 32 SYNC-DL codes 312, and different SYNC-DL codes are used between neighboring Node Bs. Accordingly, the UE performs synchronization with the 32 possible codewords and the signal of the largest intensity currently received to determine the SYNC-DL code, thereby synchronizing with the cell to which it belongs.

The UpPTS 206 is transmitted through an uplink pilot channel (hereinafter referred to as "UpPCH"), which is a physical channel, and includes a 32-chip GP 322 and a 128-chip SYNC-UL code (Synchronization Up-). link code, hereinafter referred to as " SYNC-UL " The GP 322 protects the UL signal transmitted to the TS # 1 207 from overlapping the SYNC-UL code 321. There are 256 types of SYNC-UL codes 321, and the purpose of the SYNC-UL code 321 is to use Node B to measure UpPCH to synchronize uplink of UE.

FIG. 4 is a diagram illustrating a transmitter structure of a typical UE in a LCR-TDD mobile communication system.

Referring to FIG. 4, the user data 401 includes signaling information of an upper layer and data information of a user. The user data 401 is encoded via an encoder 402. The encoding is a process of discovering or correcting an error when an error occurs during data transmission. Convolutional coding and turbo coding are used for the coding scheme, and other orthogonal coding methods for channel classification may be used. User data that has passed through the encoder 402 is interleaved in the interleaver 403. The interleaving is a process for reducing the influence of the concentration error on the data when a concentration error occurs in time for user data transmitted through a physical channel. The interleaving is to change the transmission order of the user data according to a predetermined rule when transmitting the user data, and even if a intensive error due to noise occurs during the transmission process, the positions of the errors are spread when the receiver interleaves the interleaving. Minimize the impact of the concentrated error. The user data that has passed through the interleaving 403 is input to the multiplexer (MUX) 407 and multiplexed with the TFCI 404, the SS 405, and the TPC 406 to form a user's data portion. The TFCI 404 is an indicator indicating the data rate and the combination of transmission of each type of data when several types of user data are transmitted at the same time, and serves to correctly interpret the data. The SS 405 is a command transmitted for each subframe and used to adjust DL synchronization. The TPC 406 is used for DL transmit power control from Node B to UE as a command for power control. The data unit generated by the multiplexer 407 is input to the data modulator 408 to be modulated from data in bit units to data in symbol units. This has several effects, but can basically increase the data rate. The symbol unit data from the data modulator 408 is input to the spreader 409. The symbol unit data is multiplied by a channelization code by the spreader 409. This process is called spreading. As the channel code, an OVSF code (Orthogonal Variable Spreading Factor Code: OVSF code) is used. The OVSF code is a kind of orthogonal code whose length is determined according to the data rate. The channel code distinguishes the reverse channel of each user when several users simultaneously transmit data in one time slot. In addition, it serves to spread the band in which the user's data is transmitted according to the length of the channel code. The rate at which the transmission band is spread is called a spread ratio. The product of the spreading rate and the transmission rate of user data is 1.28 Mcps in the LCR-TDD scheme. The user data portion spread by the spreader 409 is multiplied by a scrambling code 411 in the multiplier 410. The scrambling code is a code used in the third generation asynchronous mobile communication standard, and is used to reduce cross correlation between node B and user, and multipath of the same signal. In the LCR-TDD mobile communication system, only the Node B is used to lower the discrimination and cross correlation. In the LCR-TDD mobile communication system, one scrambling code is used for each Node B, and the scrambling code is used for both forward and reverse transmission.

The user data portion scrambled by the multiplier 410 is input to the multiplexer 412. Midamble 413 is provided to another input of the multiplexer 412. The multiplexer 412 multiplexes the scrambled user data unit and the midamble to form a user reverse channel. Multiplexing by the multiplexer 412 is such that the scrambled user data part is divided into two parts, and a midamble is inserted between the user data parts divided into the two parts.

The user reverse channel output from the multiplexer 412 is modulated by the modulator 413. In the LCR-TDD mobile communication system, a quadrature phase shift keying (QPSK) method or an 8 phase shift keying (8PSK) method is used as the modulation method. As another modulation method, a quadrature amplifier modulation (QAM) method may be used. The user reverse channel output from the modulator 413 is input to the switch 415. The switch 415 is controlled by the controller 416. The controller 416 adjusts the timing of transmission of the reverse channel. In addition, in the LCR-TDD mobile communication system, the switch 415 is controlled by the UpPTS transmission time, the DwPTS reception time, and the DL channel reception time from the Node B. The UpPTS is generated from the UpPTS generator 414. The UpPTS is transmitted when the UE needs to allocate a channel from the Node B or in a handover situation, so that the Node B adjusts the basis of backward transmission power determination or backward transmission synchronization of the UE. The user reverse channel output from the switch 415 is up-converted to a carrier frequency band through the radio frequency unit 417 and then radiated to the radio channel through the antenna 419.

FIG. 5 is a diagram illustrating a receiver structure of a Node B corresponding to FIG. 4.

Referring to FIG. 5, UL signals received through the antenna 500 are inputted to the switch 502 after being converted from the carrier band to the baseband by the RF unit 501. The switch 502 inputs the UL signals to the demodulator 505 at some point in time according to the controller 503. In addition, the controller 503 controls the switch 502 by identifying a time point at which UEs in the Node B transmit UL signals. That is, by connecting the switch 502 to the UpPTS interpreter 504 according to the time of receiving the UpPTS, the UpPTS from each UE can be interpreted.

The demodulator 505 demodulates the UL signal from the switch 502 and then inputs it to the demultiplexer 506. The demultiplexer 506 separates the midamble and the UL signal data from the received UL signal. The midamble is input to a midamble tracker 507. The midamble tracker 507 determines which UE is the code when the midamble has a unique code for each UE. The midamble code tracked from the midamble tracker 507 is input to a channel estimator 508. The channel estimator 508 can obtain a channel impulse response between the UE and the Node B using the midamble code. This is represented by a unique matrix value for each UE. The channel impulse response and the UL signal data portion from the demultiplexer 506 are input to a joint detector (hereinafter referred to as "JD") 509.

The JD 509 uses the inputs to generate multiple access interferences (hereinafter referred to as " MAI ") and fading channels of users at the same timeslot and frequency in a Node B-controlled cell. Inter-Symbol Interference (hereinafter, referred to as "ISI") can be effectively removed at the same time using a JD algorithm. In the Node B, the channel environment between the UE and the Node B and the transmission signal of the UE can be more accurately estimated through the JD 509.

An estimate of the signal obtained by the JD 509 is multiplied by a scrambling code 510 used in the transmitter of the UE. Thereafter, the demixed signal is multiplied by the spreading code 511 used in the transmitter of the UE to perform the despreading process. The UE signal data unit is separated for each user by the demixing process and the despreading process. The separated data part is changed from data in symbol units to data in bits through the data demodulator 512. The bit unit data is input to the demultiplexer 513.

The demultiplexer 513 separates the TFCI 514, the SS 515, the TPC 516, and the user data from the bit unit data. The TFCI 514 is used to interpret the transmission format used in the user data portion, and the SS 515 is used to adjust the DL channel transmission timing to the UE. The TPC 516 is used to control power of a DL transmission signal of a user. The user data output from the demultiplexer 513 is output as the user data 518 through a decoding chain 517 corresponding to the coding chain performed at the transmitter of the UE.

6 is a diagram showing the detailed configuration of the JD 509 in the configuration of FIG. That is, FIG. 6 shows a method of obtaining a more accurate estimate of the transmission signal from the UEs by eliminating the neighbor cell interference signal from the prior art applicable to the receiver of the base station using the LCR-TDD scheme. In FIG. 6, only a signal component caused by a transmission signal from UEs located in an adjacent cell is extracted, and a signal caused by a transmission signal from UEs located in a cell using the extracted signal component. Only the ingredients are extracted.

Referring to FIG. 6, the signal e 601 received by the base station includes a number of types of noises as well as transmission signals from UEs located in its own cell. Noise signal from the UEs. To remove the noise signal, the following process is performed. By applying JD to the received signal e 610, an estimate of the transmitted signal from UEs located in its cell 602 can be obtained. The estimate The channel path determinant of the self cell previously calculated at the base station at 602. By applying 603, an estimate of a signal transmitted from UEs located within its cell and received at the base station 604 can be obtained. The estimate at the received signal e (601) at the base station By subtracting 604, the base station received signal is a noise component excluding received signals transmitted from UEs located in its own cell. Only 605 can be obtained.

To extract the signal component for the adjacent cell among the noise components By applying the JD for 605, the transmission data estimate from the UEs located in the neighbor cell 606 can be obtained. The estimate In 606, the channel path determinant of the neighbor cell, which is calculated in advance by the base station. By applying 607, an estimate of the signal transmitted from the UEs located in the neighbor cell and received at the base station 608 can be obtained. remind By subtracting 608 from the signal e (601) received at the base station, a signal component from which interference noises of UEs coming from an adjacent cell are removed from the signal e (601) received at the base station. Only 609 can be extracted.

remind Applying JD back to 609, the first estimate Second estimate with minimized components for adjacent cells at 602 610 can be obtained. The estimate 610 is the first estimate It is a more accurate estimate than (602).

As described above, by applying the above method, a more accurate signal of the magnetic cell is estimated by considering not only the interference component in the magnetic cell but also the interference component of the adjacent cell. However, in the above-described prior art, when the interference component of the adjacent cell is obtained, the same method as the method of obtaining the interference component in the own cell using the JD algorithm is used, and no other specific method is presented. However, in the prior art, it is impossible to apply in terms of complexity in consideration of all the numerous UEs located in the neighbor cells. In addition, even when only a small number of UEs located in the neighbor cell are considered, the above-described conventional technology cannot obtain the interference component of the neighbor cell. The reason is that in FIG. 6, the base station must know the UL timeslot, the OVSF code, the scrambling code, the midamble information, etc. used by the UE located in the neighbor cell in order to perform the procedure from 806 to 809. This is because the conventional technology does not know this, and even a target UE cannot be selected.

Accordingly, an object of the present invention for solving the above problems is to provide a method for effectively detecting adjacent cell interference components in a base station receiver of a mobile communication system using a combined detector and time division duplexing.

Another object of the present invention is to select a mobile terminal that has a major influence on the interference component without considering all the mobile terminals of the neighboring cells in order to reduce the complexity in determining the UE which becomes the neighboring cell interference component. In providing.

Another object of the present invention is to provide a method and apparatus for improving reception performance in a reverse direction by effectively removing interference components from a UE located in a neighboring cell during reverse reception.

In a first aspect for achieving the above object, the present invention provides a process for selecting a UE serving as an interference component of a neighboring cell through a measurement report when a specific condition is satisfied through base station pilot strength measurement of the UE; The base station receives information such as UL time slot, OVSF code, scrambling code, and midamble allocation from the selected UE, obtains a channel path determinant using this, and performs JD only when the channel path determinant satisfies a specific condition. It is characterized by including the process of obtaining the neighbor cell interference components.

In the second aspect for achieving the above object, the present invention, considering that the attenuation according to the propagation distance of the electromagnetic wave in the actual situation is very large, the UE which acts as the actual major interference component among a plurality of UEs located in the adjacent cell The majority of s are estimated to be UEs located in the neighboring cell region close to the boundary area of their cell, and when the strength of the pilot of the base station of the neighboring cell is determined to be greater than or equal to a predetermined value by measuring the base station pilot strength of the neighboring cell, If the relative difference between the pilot strength of the base station of the cell and the base station pilot strength of the neighboring cell is greater than or equal to a predetermined value in preparation for the process of performing measurement report to the base station and the channel condition of the UE, the base station of the neighboring cell is determined. It includes the process of performing a measurement report.

In a third aspect for achieving the above object, the present invention controls a mobile terminal, a reference base station where the mobile terminal is located, a neighbor base station adjacent to the reference base station, the reference base station and the neighbor base station; And a wireless network controller, wherein the mobile station communicates with the wireless network controller through the reference base station in a time division manner, wherein the mobile station is generated at the neighboring base station by a transmission signal from the mobile terminal. In the method for removing the interference signal, if a measurement control message from the radio network controller is transmitted to the mobile terminal through the reference base station, it is determined whether the signal transmitted by the mobile terminal acts as a major interference component of the neighboring base station Recognizing and measuring the report to the wireless network controller, and to the mobile terminal The wireless network controller transmitting a reception command to the neighboring base station in response to the measurement report from the mobile station; and in response to the reception command, the neighboring base station from the mobile stations located at another base station including the reference base station. And measuring the interference component by the received signal and removing the interference component from all received signal components.

In a fourth aspect for achieving the above object, the present invention provides a device for removing interference signals generated by transmission signals from neighboring base stations in a time division mobile communication system, and outputting a measurement control message. And a wireless network controller that outputs a reception command by a measurement report corresponding to the measurement control message, and when the measurement control message is received, the signal transmitted by itself is a major interference component of a base station adjacent to a reference base station at which it is currently located. A mobile terminal for providing the measurement report to the radio network controller by recognizing whether it is operating, and the reference base station as a neighboring base station, and measures the interference component by the received signal from the mobile terminals in response to the reception command; A neighboring base station that removes the interference component from all received signal components. It is characterized by a ship.

In a fifth aspect for achieving the above object, the present invention provides a mobile terminal, a reference base station having a base station in which the mobile terminal is located as a neighbor base station, and a wireless network for controlling the reference base station and the neighbor base station. And a controller, wherein the mobile station performs time division communication with the wireless network controller through the neighboring base station, wherein the interference signal generated by the transmission signal from the mobile station is received at the reference base station. A method of removing a signal, the method comprising: inputting a received signal, estimating a signal component from a mobile terminal located at the reference base station from the received signal, and removing the signal component from the received signal to output a first noise component signal; Input a noise component signal, and shift the signal from the first noise component signal to the Outputting a data component signal by estimating a signal component from the mobile terminal to remove from the received signal, and inputting the data component signal, the signal component from the mobile terminal located at the reference base station from the data component signal Estimating and outputting the reference base station estimate data from which the noise component is removed.

In a sixth aspect for achieving the above object, the present invention provides a mobile terminal, a reference base station having a base station in which the mobile terminal is located as a neighbor base station, and a wireless network for controlling the reference base station and the neighbor base station. And a controller, wherein the mobile station performs time division communication with the wireless network controller through the neighboring base station, wherein the interference signal generated by the transmission signal from the mobile station is received at the reference base station. An apparatus for removing a signal, comprising: a reference base station weight that inputs a received signal, estimates a signal component from a mobile terminal located in the reference base station from the received signal, and outputs a reference received signal component corresponding to first reference base station estimated data; First noise by removing the reference received signal component from the government and the received signal A first subtractor for outputting a component signal and a peripheral base station for inputting the first noise component signal and estimating a signal component from a mobile terminal located in the peripheral base station from the first noise component signal to output a noise component signal An estimator and a second subtractor for outputting a data component signal by removing the noise component signal from the received signal, wherein the reference base station estimator inputs the data component signal and uses the reference from the data component signal. And estimating signal components from the mobile station located in the base station and outputting second reference base station estimation data from which the noise components are removed.

1 is a view showing a general configuration of a wireless access network in a mobile communication system using the LCR-TDD scheme.

2 is a view showing a radio frame structure in a mobile communication system using a conventional LCR-TDD scheme.

FIG. 3 is a diagram illustrating a structure of a time slot, a forward pilot time slot, and a reverse pilot time slot shown in FIG.

4 is a diagram illustrating a structure of a transmitter of a general mobile terminal in an LCR-TDD mobile communication system.

FIG. 5 is a diagram illustrating a receiver structure of a base station corresponding to FIG. 4. FIG.

6 is a view showing a detailed configuration of the coupling detector in the configuration of FIG.

7 is a diagram illustrating signaling performed in an LCR-TDD mobile communication system according to an embodiment of the present invention.

FIG. 8 is a view for explaining an example for determining whether a mobile terminal satisfies a specific condition in which a signal transmitted by the mobile terminal acts as a major interference component to an adjacent base station in FIG.

9 is a view showing a control flow performed in a mobile terminal for an embodiment of the present invention.

10 is a diagram illustrating a control flow performed by a neighbor base station of a mobile terminal for an embodiment of the present invention.

11 is a diagram illustrating a receiving apparatus in a base station according to an embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

DETAILED DESCRIPTION In the following detailed description, one representative embodiment of the present invention is set forth in order to achieve the above technical problem. And other embodiments that can be presented with the present invention are replaced by the description in the configuration of the present invention.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

7 is a diagram illustrating signaling performed in an LCR-TDD mobile communication system according to an embodiment of the present invention. That is, a process for effectively detecting neighbor cell interference components in a base station receiver is shown. In FIG. 7, the UE 704 is located in a service area controlled by the Node B1 702 and communicates with the RNC 1 701 through the Node B1 702. Node B2 703 is a base station adjacent to Node B1 702. The Node B1 702 and the Node B2 703 are controlled by the RNC1 701. As described above, in the configuration shown in FIG. 7, the RNC 1 701 connected to the CN manages the Node B 1 702 and the Node B 2 703. One of several UEs existing in the cell of the Node B 1 703 is called a UE 704, and an adjacent cell Node B 2 703 exists in the Node B 1 702.

Referring to FIG. 7, the UE 704 existing in the cell area of the Node B 1 702 managed by the RNC 1 701 sends a MEASUREMENT CONTROL message 705 from the RNC 1 701 to the Node B 1. Receive via 702. The UE 704 receives the MEASUREMENT CONTROL message 705 to perform a measurement process 706 for receiving system information that is broadcast in various Node Bs. The UE 704 approaches the cell of the Node B 2 703 while performing the measurement process 706, so that if a specific condition is satisfied in step 707, a signal transmitted from the UE 704 is received by the UE 704. Recognize that it is a major neighboring cell interference component of. Recognizing this, the UE 704 performs a measurement report 708 for informing the RNC 1701. The above-mentioned specific condition is an important condition for determining the interference component of the neighbor cell in the Node B, which will be described later with reference to FIGS. 8 and 9.

The RNC 1 701 receiving the measurement report 708 transmits a reception command message 709 to the Node B 2 703. In the reception command message 709, a UL timeslot, an OVSF code, a scrambling code, a midamble assignment, and the like, which are basic information for channel estimation from the UE 704, are transmitted. After receiving the Reception Command message 709, the Node B 2 703 can distinguish and receive a signal of a UE of a neighbor cell, which has been regarded as a noise until now, and this process is a reception process 710. . The Node B 2 703 performs a joint channel estimation (hereinafter referred to as "JCE") 711 process from the signal received in the reception process 710. The Node B 2 703 obtains a channel path determinant through the JCE process 711, thereby performing the JD operation 712 on the adjacent cell. Thereafter, the Node B 2 703 having completed the above processes may extract only the interference component 713 of the adjacent cell by performing the JD operation 712. A detailed description of operations from the reception process 710 to the JD operation 712 will be described later with reference to FIG. 10.

The operation described by FIG. 7 assumes a case where a transmission signal from a UE 704 belonging to a cell of Node B 1 702 becomes an interference component of a main neighbor cell of Node B 2 703. Further, as an application example, the UE may belong to a cell of the Node B 2 703, and the above-described operation may be applied in the same manner even when the transmission signal of the UE becomes an interference component of a major neighbor cell of the Node B 1 702. In the case where the adjacent cell of the Node B 1 702 is a cell of a third Node B managed by the RNC 1 701 instead of the Node B 2, the above-described operation may be applied in the same manner. In addition, the neighbor cell of Node 1 702 is a third Node B managed by another RNC connected with RNC 1 701, and the transmission signal from UE 704 is the main interference component of the third Node B. In this case, the above-described operation may be equally applied. In this case, another connected RNC plays the role of RNC 1 701 and the third Node B plays the role of Node B 2 703. At this time, when connected to the CN, it is connected through the RNC 1 (701).

FIG. 8 illustrates an example for determining whether a UE satisfies a specific condition in which a signal transmitted by the UE through a measurement process 706 serves as a major interference component for an adjacent Node B in FIG. 7. to be. An example shown in FIG. 8 is a method of using pilot intensities of Node Bs per region.

In FIG. 8, the horizontal axis 801 represents a spatial region that actually exists, and the vertical axis 802 represents a pilot power intensity (P _pilot ) from Node B. Each of the two graphs shown in FIG. 8 represents a pilot power intensity 803 of Node B 1 and a pilot power intensity 804 of Node B 2 that vary according to regions.

Looking at the values present in the direction of the horizontal axis 801, Cell A 805 on the left and Cell on the right, respectively, based on the point where the pilot intensity 803 of Node B 1 and the pilot intensity 804 of Node B 2 meet. It is denoted by B 806. The base station of Cell A 805 is Node B 1, and the base station of Cell B 806 is Node B 2. The region of the horizontal axis 801 is further divided into a region 807, b region 808, and c region 809 based on the value of the vertical axis. Assuming that a UE exists in the Cell A 805, the area a 807 is an area where the UE exists in the Cell A 805, and the b area 808 indicates that the UE is located in the Cell A 805. ) And the neighboring cell interference component of Node B 2. The c region 809 is an area where the UE makes a hard handover to the Cell B 806.

Looking at the value present in the vertical axis 802 of the Node B 2, P _Handover 810 represents the pilot strength that hard handover between cells occurs, P _ACI 811 is a Node that the UE corresponds to the neighboring cell It represents the pilot strength at which B is regarded as the interference component. The difference between the pilot power intensity 803 of Node B 1 and the pilot power intensity 804 of Node B 2 or the difference between the pilot power intensity 804 of Node B 2 and the pilot power intensity 803 of Node B 1 If the value is ΔP (which is always greater than 0), the values of P _{diff A} 812 and P _{diff H} 813 are ΔP values indicated by arrows in the figure.

9 is a diagram illustrating a control flow performed by a UE for an embodiment of the present invention. That is, it is a diagram illustrating a specific operation for a measurement and a measurement report for determining whether a signal transmitted from the UE serves as a major interference component of an adjacent cell. In FIG. 9, when referring to FIG. 8, it is assumed that a UE in Cell A 805 moves toward Cell B 806. However, the procedure to be described later may be equally applicable to the case where the UE moves from Cell B 806 to Cell A 805. Meanwhile, even if the number of cells is not only two but more cells exist, the procedure to be described later may be applied.

In FIG. 9, the UE in Cell A 805 and communicating with Node B 1 performs a measurement process. If it is determined that the signal transmitted by the UE is an interference component of an adjacent cell during measurement, the RNC responds to this event. It describes the process of performing a measurement report.

Referring to FIG. 9, when the UE starts a measurement process in step 901, the UE proceeds to step 902 to initialize a variable value of T _count to '0'. Thereafter, the UE proceeds to step 903 and performs pilot power strength of Node B 1 ( ) And the pilot power strength of Node B 2 ( Measure how much) is.

In operation 904, the result of the measurement determines whether the condition of Equation 1 is satisfied.

If the condition of Equation 1 is not satisfied, the UE returns to step 902 to repeat the above process. However, if the condition of Equation 1 is satisfied, the process proceeds to step 905. Satisfying the condition of Equation 1 means that the UE moves from the region a region 807 to the region b in FIG. 8. The UE present in the b area 808 should inform the RNC that it is a neighbor cell interference component. However, it is not desirable to report the measurement to the RNC immediately because the UE has moved to the b area 808 so that the RNC notifies the Node B 2 of this. This is because a so-called ping pong phenomenon, ie, a case where a UE does not stay at one of the a, b, and c regions for a certain time and continues to move back and forth between the boundaries. Therefore, it is reasonable to make a measurement report only when the UE exists in the b area 808 for a predetermined time or more. As described above, the process of making the measurement report only when the UE exists in the b region 808 for a predetermined time is performed in steps 905 and 906.

If the UE satisfies the condition of Equation 1 in step 904, the UE proceeds to step 905 to increase the T _count value by '1'. Wherein the _count value T is increased to the UE in step 906 compares the _count value T and a predetermined constant threshold value T _{count_Threshold.} In step 907, if the T _count value is greater than the T _{count_Threshold} , the comparison proceeds. Otherwise, if the T _count value does not have a value larger than a predetermined predetermined threshold value T _{count_Threshold} , the process returns to step 902 to repeat the above process. In step 907, the UE reports measurement to report to the RNC that a situation in which the UE satisfies the condition of the interference component of the neighbor cell occurs. After that, all the operations according to the embodiment of the present invention are terminated.

In the above-described operation, repeating steps 902 to 905 until the T _count value reaches T _{count_Threshold} indicates that the signal transmitted from the UE is transmitted only if the UE stays in the b region continuously for a predetermined time or more. It is considered to act as an interference component of.

9 illustrates a control flow for determining that a signal transmitted from a UE is an interference component of a neighbor cell. However, in FIG. 8, when the UE in the b area is transferred to the c area, the UE should perform hard handover. The conditions for determining this are as shown in Equation 2 below.

The UE continuously measures the pilot strength of the neighboring base station while in the b region, and performs a hard handover procedure when the condition as shown in Equation 2 is satisfied. That is, if any of the condition of the <Equation 2>, in the same manner as when determining that the interference component with respect to the neighboring cell jeonghaeseo the threshold value of the T _count value is greater is the T _count value than the threshold value, hard to RNC Perform a measurement report of handover. The base station receiving the measurement report according to the hard handover from the UE removes the UE from the neighbor cell interference component and starts a normal hard handover procedure.

FIG. 10 is a diagram illustrating a control flow performed by Node B2, which is a neighbor base station of a UE, for an embodiment of the present invention. That is, as a procedure of calculating a neighbor cell interference component by receiving a signal transmitted from the UE, detailed operations from the reception process 710 to the joint detection operation 712 in FIG. 7 are described. In the following description, when the value of the channel estimation determinant among UEs reported as interference components when the base station determines that the predetermined threshold value does not continuously exceed, it is determined that the transmission signal from the UE does not act as an adjacent cell interference component. The procedure to exclude from neighboring cell interference components is described.

Referring to FIG. 10, the Node B 2 starts the reception process in step 1001. Before the reception process starts, the Node B 2 receives basic information for channel estimation and joint detection from a corresponding RNC through a Reception Command message. The basic information may be UL timeslot, OVSF code, scrambling code, midamble allocation, and the like. When the reception process starts, the Node B 2 sets a variable 'Count' indicating the number of JD failures to '0' in step 1002. After that, the Node B 2 performs a JCE operation in step 1003. The JCE operation is performed in subframe units. The JCE operation may be performed by receiving a midamble of a UE located in an adjacent cell. The Node B 2 performs the JCE operation, Can be obtained. remind (i: number of neighbor cells, k: number of UEs) indicates a channel impulse response of a k-th UE located in an i-th neighbor cell. The channel impulse response becomes an input value of the following process. In step 1004, the Node B 2 compares the energy of the channel impulse response with a predetermined threshold value. If the energy of the channel impulse response is greater than a predetermined threshold value, the Node B 2 regards the transmission signal from the UE as an interference component of a primary neighbor cell, and proceeds to step 1005 to initialize the Count value to '0'. After proceeding to step 1006. The Node B 2 proceeds to step 1006 by performing a JD operation, thereby obtaining the interference component caused by the signal received from the UE. In step 1007, the next subframe is designated, and then the method returns to step 1003 to repeat the above-described procedure.

However, if it is determined by the comparison that the energy of the channel impulse response is not greater than the threshold, the received signal from the UE is not regarded as an interference component of the primary neighbor cell. If so, the Node B 2 proceeds to step 1008 to increase the Count value by 1 and proceeds to step 1009. In step 1009, the Node B 2 compares the Count value with a predetermined threshold Threshold_Count value. According to the comparison, if the Count value is greater than the Threshold_Count value, it is assumed that the received signal from the UE is not the interference component of the primary neighbor cell, and the UE is excluded from the neighbor cell interference component in step 1011. The operation according to the example ends. However, if the count value is not greater than the Threshold_Count value by the comparison, the next subframe is designated in step 1010 and the method returns to step 1003 to repeat the above-described operation.

11 is a diagram illustrating a reception device in a base station according to an embodiment of the present invention. In the following description, detailed descriptions of operations duplicated with or related to the present invention will be omitted.

Referring to FIG. 11, the signal e input from the antenna 1101 may be a reception signal in which all noises present in nature and transmission signals transmitted from UEs located in neighboring cells and self cells are mixed. The signal e is input to the demultiplexer 1102, and is separated into a midamble and a data portion by the demultiplexer 1102. The separated data portion is input to the coupling detector 1107, and the separated midamble is input to the midamble tracker 1103 and then through the channel estimator 1104, thereby deducting the channel path determinant of the own cell. Is obtained. In the process of obtaining the channel path determinant, since a cell is synchronized with a radio frame, a correlator is used in an actual implementation. The obtained channel path determinant Is input to the coupling detector 1107. The coupling detector 1107 receives a scrambling code, an OVSF code, and a data portion in addition to the channel path determinant to estimate transmission data of UEs located in the cell. The estimated data is the first estimated data of the data transmitted by the UEs located in the cell. to be. The estimation data is not a signal generated only from the self-cell UEs, but is obtained from a signal coming from a UE located in an adjacent cell and a signal mixed with various noises. Therefore, in the present invention, the following process is continued to remove the signal component coming from the UE located in the neighbor cell from the first estimated data of the UE.

remind Is multiplied by multiplier 1109 Multiply by Is output. remind Is input to the subtractor 1110 and subtracted from the received signal e. The signal output by the subtractor 1110 may be represented by Equation 3 below.

Looking at the meaning of Equation (3), the received signal component from the UE located in its cell from the received signal e By subtracting the value of, it is possible to obtain an estimate of a signal in which several noises in the natural world and a received signal from a UE located in an adjacent cell are combined, that is, an estimate of a noise component from the perspective of its cell. Here, the noise signal Speak, the signal It is possible to estimate the received signal from the UE located in the neighboring cell from. The signal Is input to the demultiplexer 1111, and separates the midamble and the data portion. The separated data portion is input to the coupling detector 1115, the separated midamble is input to the midamble tracker 1112, and then passes through the channel estimator 1113, whereby a channel path determinant of adjacent cells is obtained. Is obtained. In the process of obtaining the channel path determinant, since adjacent cells do not synchronize with each other unlike their own cells, a matched filter that is not a correlator may be used in an actual implementation. The obtained channel path determinant Is input to the coupling detector 1115. In addition to the channel path determinant, the coupling detector 1115 receives a scrambling code, an OVSF code, and a data portion used in the UE of the neighbor cell as inputs, and transmits data of UEs located in the neighbor cell. Estimate The estimated data is UE estimation data located in an adjacent cell to be.

If the number of neighboring cells is plural (N), a plurality of (N) estimators including configurations (reference numerals 1111 to 1117) for estimating transmission data of the UE will be required. There will also be N estimated data available for the UE. It is assumed here that N = 1 for the sake of calculation.

Estimation of Transmission Data of UE Located in Adjacent Cell Obtained as Above By using, it is possible to obtain more accurate estimation data for the transmission data of the UE located in its own cell. This process is as follows.

remind Is multiplied by multiplier 1118 Multiply by The output signal is input to the subtractor 1119 and subtracted from the received signal e. The signal output by the subtractor 1119 may be represented by Equation 4 below.

Looking at the meaning of Equation 4, the received signal component from the UE located in the adjacent cell from the received signal e By subtracting the value of, the signal can obtain e_ref from which the noise signal component from the UE located in the neighbor cell is removed.

The signal e_ref is input to the demultiplexer 1102 again, and is separated into a midamble and a data part by the demultiplexer 1102. The first estimated data obtained by applying this again to the above-described configuration of reference numerals 1103 to 1108 More Accurate Estimation Data without Interference Components from Adjacent Cells in Can be obtained. The data is the second estimated data of the data transmitted by the UEs of the own cell to be finally obtained in the present invention. That is, as described above, the second estimation data is more accurate estimation data in which neighbor cell interference components due to UEs located in neighbor cells are removed.

As described above, in the third generation mobile communication system using the TD-CDMA scheme, when the mobile terminals become interference components of neighboring cells instead of their own cells, the base station of the neighboring cells is configured to reduce the interference components among all received signals. By accurately finding and removing, it is possible to more accurately estimate the data received from the mobile terminal in its cell.

Claims (17)

A mobile station, a reference base station in which the mobile terminal is located, a neighbor base station adjacent to the reference base station, and a wireless network controller controlling the reference base station and the neighbor base station, wherein the mobile terminal is configured to access the base station through the reference base station. In a mobile communication system performing a time division communication with a radio network controller, a method for removing an interference signal generated in the peripheral base station by a transmission signal from the mobile terminal, When a measurement control message is transmitted from the radio network controller to the mobile station through the reference base station, the radio network controller recognizes whether the signal transmitted by the mobile terminal acts as a major interference component of the neighboring base station and reports the measurement to the radio network controller. Process, Transmitting, by the radio network controller, a reception command to the neighboring base station in response to the measurement report from the mobile terminal; In response to the reception command, the neighboring base station measures an interference component due to a received signal from mobile terminals located at other base stations including the reference base station, and removes the interference component from all received signal components. Said method comprising: a. The method of claim 1, wherein the measurement report is performed. A first power intensity measured by the signal from the reference base station ( ) And the second power strength measured by the signal from the neighboring base station ( Judging whether () satisfies the condition of Equation 5 below, And measuring and reporting to the radio network controller that the signal transmitted by the mobile terminal acts as a major interference component of the neighboring base station if the condition satisfying the condition of Equation 5 is maintained for a certain time. Characterized in that the method. Here, P _ACI is a predetermined threshold power value for identifying a major interference component, and P _diffA is a power intensity difference between the reference base station and the neighboring base station at any time. The method of claim 1, wherein the measuring of the interference component comprises: Receiving a midamble from the mobile terminal and obtaining a channel impulse response of the mobile terminal by the midamble; And if the channel impulse response satisfies a predetermined threshold, measuring the interference component caused by the received signal by applying joint detection to the received signal from the mobile terminal. 4. The method of claim 3, further comprising determining that the received signal from the mobile terminal does not act as an interference component if the channel impulse response does not satisfy the predetermined threshold value for a predetermined time period. Characterized in that the method. The method as claimed in claim 4, wherein the neighboring base station further comprises receiving information from the mobile terminal for receiving the midamble from the mobile terminal. An apparatus for removing an interference signal generated by a transmission signal from a neighboring base station in a time division mobile communication system, A wireless network controller for outputting a measurement control message and outputting a reception command by a measurement report corresponding to the measurement control message; Receiving the measurement control message, the mobile terminal for recognizing whether the signal transmitted by the self acts as a major interference component of the base station adjacent to the current base station and provides the measurement report to the radio network controller; The reference base station is a neighboring base station, and in response to the reception command comprises a neighboring base station for measuring the interference component by the received signal from the mobile terminal, and removes the interference component from all received signal components The apparatus described above. The mobile station of claim 6, wherein the mobile station comprises a first power intensity measured by a signal from the reference base station. ) And the second power strength measured by the signal from the adjacent base station ( Is measured by the radio network controller and reports that the signal transmitted by itself serves as a major interference component of the neighboring base station when the condition that satisfies the condition of Equation 6 is maintained for a certain time. Device. Here, P _ACI is a predetermined threshold power value for identifying a major interference component, and P _diffA is a power intensity difference between the reference base station and the neighboring base station at any time. The mobile station of claim 6, wherein the neighbor base station receives the midamble from the mobile station, obtains a channel impulse response of the mobile station by the midamble, and if the channel impulse response satisfies a predetermined threshold value, And applying interference detection to the received signal from the mobile terminal to measure the interference component caused by the received signal. The method of claim 8, wherein the neighboring base station determines that the received signal from the mobile terminal does not act as an interference component when the channel impulse response does not satisfy the predetermined threshold value for a predetermined time. Said device. 10. The apparatus as claimed in claim 9, wherein the neighboring base station receives information from the mobile terminal for receiving the midamble from the mobile terminal. A base station having a mobile station, a base station where the mobile terminal is located as a neighbor base station, and a wireless network controller controlling the reference base station and the neighbor base station, wherein the mobile terminal is configured to control the radio network controller through the neighbor base station; In the mobile communication system for performing a time division and the communication by the method, in the reference base station to remove the interference signal generated by the transmission signal from the mobile terminal, Outputting a first noise component signal by inputting a received signal, estimating a signal component from a mobile terminal located in the reference base station from the received signal and removing the signal component from the received signal; Inputting the first noise component signal, estimating a signal component from a mobile terminal located in the neighboring base station from the first noise component signal and removing the signal component from the received signal to output a data component signal; Inputting the data component signal, estimating a signal component from a mobile terminal located in the reference base station from the data component signal, and outputting the reference component estimation data from which the noise component is removed; . The method of claim 11, wherein the outputting of the first noise component signal comprises: Separating a midamble and a data signal from the received signal, and obtaining a channel path determinant of the reference base station by the midamble; Obtaining first estimation data of the reference base station by performing joint detection by inputting the data signal, the channel path determinant of the reference base station and the scrambling code and the channelization code used in the mobile terminal; Outputting a reference received signal component by multiplying the first estimated data by the channel path determinant; And subtracting the reference received signal component from the received signal to output the first noise component signal. The method of claim 11, wherein the outputting of the data component signal comprises: Separating a midamble and a data signal from the first noise component signal, and obtaining a channel path determinant of the neighboring base station by the midamble; Obtaining neighbor base station estimation data due to a transmission signal from the neighboring base station by performing joint detection by inputting the data signal, the channel path determinant of the neighboring base station, the scrambling code and the channelization code used in the mobile station; , Outputting a noise component signal by multiplying the neighbor base station estimation data by the channel path determinant; And subtracting the noise component signal from the received signal to output the data component signal. The method of claim 11, wherein the outputting of the reference base station estimation data comprises: Separating a midamble and a data signal from the data component signal, and obtaining a channel path determinant of the reference base station by the midamble; Combination detection is performed by inputting the data signal, the channel path determinant of the reference base station, the scrambling code and the channelization code used in the mobile station, and obtaining second estimation data of the reference base station to output the data as the reference base station estimation data. Said method comprising the steps of: A base station having a mobile station, a base station where the mobile terminal is located as a neighbor base station, and a wireless network controller controlling the reference base station and the neighbor base station, wherein the mobile terminal is configured to control the radio network controller through the neighbor base station; In the mobile communication system for performing a time division communication with the apparatus, the reference base station to remove the interference signal generated by the transmission signal from the mobile terminal, A reference base station estimator for inputting a received signal, estimating a signal component from a mobile terminal located in the reference base station from the received signal, and outputting a reference received signal component corresponding to first reference base station estimation data; A first subtractor for outputting a first noise component signal by removing the reference received signal component from the received signal; A neighbor base station estimator for inputting the first noise component signal, estimating a signal component from a mobile terminal located in the neighbor base station from the first noise component signal, and outputting a noise component signal; A second subtractor for outputting a data component signal by removing the noise component signal from the received signal, The reference base station estimator inputs the data component signal, estimates a signal component from a mobile terminal located in the reference base station from the data component signal, and outputs second reference base station estimation data from which noise components have been removed. Said device. The method of claim 15, wherein the reference base station estimator, A demultiplexer for separating a midamble and a data data signal from the received signal or the data component signal; A midamble detector and a channel estimator for obtaining a channel path determinant of the reference base station by the midamble; Combination detection is performed by inputting the data signal, the channel path determinant of the reference base station, the scrambling code and the channelization code used in the mobile station, and thereby estimating the first reference base station estimation data or the second reference base station of the reference base station. A combined detector for outputting data, And a multiplier outputting the reference received signal component by multiplying the first reference base station estimated data by the channel path determinant. The method of claim 15, wherein the neighbor base station estimator, A demultiplexer separating the midamble and the data signal from the first noise component signal; A midamble detector and a channel estimator for obtaining a channel path determinant of the neighboring base station by the midamble; Combining the data signal, the channel path determinant of the neighboring base station, and the scrambling code and the channelization code used in the mobile station to perform joint detection, thereby outputting the neighbor base station estimation data due to the transmission signal from the neighboring base station Detectors, A multiplier for multiplying the neighbor base station estimated data by the channel path determinant and outputting the noise component signal; And a subtractor outputting the data component signal by subtracting the noise component signal from the received signal.