KR20070048424A - Method and apparatus for canceling neighbor cell interference signals in orthogonal frequency division multiple access system - Google Patents

Abstract

The present invention relates to a method and apparatus for removing interference signals when receiving data in an OFDMA system. The method of the present invention provides a method for removing interference signals from a receiver of an OFDMA system. A first process of selecting interference signals whose difference between the CINR and the measured CINR of the neighboring base station satisfies a predetermined threshold value, a second process of selecting and detecting the selected interference signals, and detecting the detected interference signal And a fourth process of removing the regenerated interference signal from the signal of the serving base station. In the receiver of the OFDMA system, the apparatus of the present invention is a receiver for receiving and processing a signal transmitted from a base station, and when the difference between a CINR of a serving base station and a CINR of a neighboring base station satisfies a predetermined threshold, the receiver receives the received signal. An interference signal canceller for regenerating the interference signal, a multiplier for multiplying the regenerated interference signal and a channel estimated signal value, a subtractor for removing the multiplied signal from the signal of the serving base station, and the interference signal And controlling the operation of the interference signal canceller by determining the interference signal in the largest order.

OFDMA, Frequency Reuse Factor, DL-MAP, DL-Burst

Description

METHOD AND APPARATUS FOR CANCELING NEIGHBOR CELL INTERFERENCE SIGNALS IN ORTHOGONAL FREQUENCY DIVISION MULTIPLE ACCESS SYSTEM}

1 is a diagram illustrating an example of a terminal located in a region where three base stations overlap in an OFDMA system

2 is a block diagram illustrating a transmitter in an OFDMA system

3 is a block diagram illustrating a receiver in an OFDMA system.

4 illustrates an example of a frame structure of an OFDMA system.

5 is a flowchart illustrating a signal processing procedure for DL burst decoding of an OFDMA receiver

6 is a block diagram showing a receiver in an OFDMA system according to a first preferred embodiment of the present invention.

7 is a block diagram showing a receiver in an OFDMA system according to a second preferred embodiment of the present invention.

8 is a block diagram showing a receiver in an OFDMA system according to a third preferred embodiment of the present invention.

9 is a flowchart illustrating a signal processing procedure in a receiver according to the present invention.

10 is a graph showing the change in the CINR strength of the serving base station and the target base station according to the distance during handover

11 is a flowchart illustrating a process of removing an interference signal of a target base station, which is an interfering base station, during handover in a terminal;

12 is a graph showing the performance results of the conventional receiver and the receiver according to the present invention.

The present invention relates to a method and apparatus for receiving data in an Orthogonal Frequency Division Multiple Access (OFDMA) system, and more particularly, to a method and apparatus for removing interference signals when receiving data in an OFDMA system.

Currently, the WiBro system, an IEEE 802.16 based OFDMA system, is based on a frequency reuse factor of 1. When the frequency reuse factor is 1, there is an excellent advantage in terms of frequency efficiency, but there is a disadvantage in that all used subcarriers overlap with the subcarriers of neighboring base stations and act as interference between each other. Due to the interference signal of the neighboring base station, the terminal located near the boundary of the cell has a deterioration in reception performance, and also a phenomenon that communication is lost during handover.

1 is a diagram illustrating an example of a terminal located in an area where three base stations overlap in an OFDMA system. In order to overcome the interference signal problem at the cell boundary 101, 103, 105, and 107 as shown in FIG. 1, the IEEE802.16 standard transmits a base station transmission signal in a low modulation order such as QPSK. It modulates, applies low Forward Error Correction (FEC) Code Rate, and uses Repetition Coding up to 6 times. However, despite these efforts, the existing terminal receiver has a high outage probability near the cell boundary on the fading channel, and handover performance is also deteriorated. In order to fundamentally overcome this problem, the frequency reuse factor must be brought to 3, but in this case, the frequency efficiency is reduced to 1/3 compared to the frequency reuse factor 1, and the cell planning becomes complicated. It's a very reluctant way. For example, in the conventional CDMA mobile communication system, the frequency reuse factor is 1.

There are many ways to improve the receiver's reception performance. For example, a method of obtaining receive diversity by using two or more antennas in a receiver. This method has the advantage that the reception performance is improved by more than 3dB by using only two reception antennas, but in this case, the complexity of the receiver is greatly increased, and the degradation of performance due to the interference signal is not greatly improved. there is a problem. The most important part of the reception performance is the reception of DL-MAP. Since the DL-MAP is a signal broadcast to all terminals in the base station, there is a problem that it is difficult to improve the DL-MAP reception performance even if a smart antenna technology or MIMO technology applied to an individual terminal is applied. In addition, the problem of poor reception performance near the cell boundary causes another big problem of poor handover performance.

Accordingly, an object of the present invention is to provide a method and apparatus for improving received signal performance in an OFDMA system.

Another object of the present invention is to provide a signal receiving method and apparatus for improving the performance of handover by removing interference signals in an OFDMA system.

In order to achieve the above object, the present invention provides a method for canceling an interference signal in a receiver of an orthogonal frequency division multiple access (OFDMA) system, and includes a carrier to interference noise ratio of a neighboring base station. The first step of measuring a CINR, and selecting interference signals for which a difference between the CINR of the serving base station and the measured neighboring base station satisfies a predetermined threshold value, and selecting and detecting the selected interference signals. And a third process of regenerating the detected interference signal and a fourth process of removing the regenerated interference signal from the signal of the serving base station.

In the first process, the interference signal is identified using a base station identifier (BSID) of the neighboring base station.

The second process includes determining an interference signal in the largest order of the interference signal, receiving the determined interference signal to compensate for the channel, and converting the channel compensated interference signal into subchannels by a predetermined permutation rule. Converting, repeating combining the interference signal converted into the subchannel form, demapping the repeatedly combined interference signal, and forward error correction (FEC decoding) of the demapped signal Characterized in that the process is performed.

The FEC decoding is characterized by performing a forward channel (FCH) and downlink information (Downlink-MAP: DL-MAP).

The third process includes detecting, encoding, and mapping the decoded interference signal, repeating the mapped interference signal a predetermined number of times, mixing the imaginary repeated interference signal in a subcarrier form, and And scramble the interference signal mixed with the subcarriers, and multiply the scrambled interference signal with the channel estimated signal.

According to an aspect of the present invention, a receiver of an Orthogonal Frequency Division Multiple Access (OFDMA) system includes a receiver for receiving and processing a signal transmitted from a base station, and a noise and interference ratio of a carrier of a serving base station. (Carrier to Interference Noise Ratio: CINR) and the difference between the CINR of the neighboring base station satisfies a predetermined threshold, the interference signal canceller for regenerating the interference signal received by the receiver, the regenerated interference signal and the channel estimation A multiplier for multiplying signal values, a subtractor for removing the multiplied signal from the signal of the serving base station, and a control unit for controlling the operation of the interference signal canceller by determining an interference signal in the largest order of the interference signal Characterized by including.

The signal interference canceller includes: an encoder for detecting and encoding an interference signal decoded from the receiver, a symbol mapper for mapping the encoded interference signal,

A repeater for repeating the mapped interference signal a predetermined number of times, a subcarrier allocator for mixing the repeated interference signal in a subcarrier form according to a predetermined permutation rule, a scrambler for scrambled the subcarrier type interference signal, and the scrambled And a multiplier configured to multiply the interference signal with the channel estimated signal by the receiver.

The interference signal canceller is a slicer that detects an interference signal repeatedly combined from the receiver, a repeater that repeats the detected interference signal a predetermined number of times, and a subcarrier that mixes the repeated interference signal in a subcarrier form by a predetermined permutation rule. And a carrier allocator, a scrambler that scrambles the subcarrier permutated interference signal, and a multiplier that multiplies the scrambled interference signal with a channel estimated signal at the receiver.

DETAILED DESCRIPTION Hereinafter, a detailed description of preferred embodiments of the present invention will be described with reference to the accompanying drawings. It should be noted that the same components in the figures represent the same numerals wherever possible. Specific details are set forth in the following description, which is provided to aid a more general understanding of the invention. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

The present invention proposes a method and apparatus for canceling an interference signal to improve reception performance in a receiver of an OFDMA system. In the following description, first, an OFDMA system will be described in order to help understanding of the present invention, and then a method and apparatus according to the present invention will be described.

2 is a block diagram illustrating a transmitter 200 in an OFDMA system.

Referring to FIG. 2, source data encoded by the FEC encoder 201 is passed through a symbol mapper 203 and modulated into a signal such as QPSK / 16QAM / 64QAM. Modulation). The modulated signal is repeated according to the repetition number set by the base station by the repetition unit 205. The repeated signals are assigned to subcarriers by being mixed in a predetermined order by subcarrier permutation 207 having a unique rule for each base station. The subcarriers are multiplied by a scrambling sequence having a unique value for each base station by a scrambler 209, and transmitted through an Inverse Fast Fourier Transform (IFFT) 211. Is made. If this is expressed as an expression, it is as follows.

When the output of the symbol mapper 203 is defined as s (m), it is expressed as in Equation 1 below.

Where M represents the length of the symbol.

Since the output of the repetition (205) is to repeat the s (m) R times, it can be represented by the following equation (2).

Since M is the length of a symbol and N is the length of a symbol to which R repetitions are applied, the following relationship is established.

By subcarrier permutation (207), the symbols are ordered by a predetermined rule and are represented by Equation 4 below.

Here, P (k) is a sequence of 1: 1 mapping with values between 0 and N-1 determined by a certain rule. If the scrambling sequence having a value of 1 or -1 is c (k), the Scrambler output x (k) is as shown in Equation 5 below.

In addition to the serving cell, the receiver side of the terminal also receives a neighbor cell interference signal from the neighboring base station. Assuming only one interference signal, the received signal y (k) is expressed by Equation 6 by adding noise signal n (k).

는 서빙 셀(Serving Cell) 기지국과 단말기 사이의 k번째 부채널에 해당하는 채널의 주파수 응답(Frequency Response of the Channel)이고, h_I(k) 이웃 셀(Neighbor Cell) 기지국과 단말기 사이의 채널 주파수 응답이다. 이 때, 신호 s(m)의 Power를 1로 가정하고, s(m), h(k), 그리고 n(k)가 서로 독립적(independent)이라고 가정 하면, 채널의 캐리어 대비 잡음 및 간섭비(Carrier to Interference Noise Ratio : CINR)는 다음의 <수학식 7>과 같이 표현 될 수 있다.here

Is the frequency response of the channel corresponding to the k-th subchannel between the serving cell base station and the terminal, and h _i (k) channel frequency between the neighbor cell base station and the terminal. Is the answer. In this case, assuming that the power of the signal s (m) is 1, and that s (m), h (k), and n (k) are independent of each other, the noise and interference ratio of the carrier of the channel ( Carrier to Interference Noise Ratio (CINR) can be expressed as Equation 7 below.

3 is a block diagram illustrating a receiver in an OFDMA system.

Referring to FIG. 3, the received signal y (k) passes through a descrambler 303 and is represented by Equation 8 below.

는 서빙 셀(Serving Cell)의 스크램블링 시퀀스(Scrambling Sequence)이다. 채널 추정기(Channel Estimator)(305)로부터 추정된 채널을 이용하여 채널 보상(Channel Compensation)을 하면 다음의 <수학식 9>와 같이 나타낸다.here

Is a scrambling sequence of the serving cell. When channel compensation is performed using the channel estimated from the channel estimator 305, Equation 9 is expressed as follows.

Here, (*) means complex conjugate. The permutated subcarriers are arranged as shown in Equation 10 through subcarrier ordering 309.

Here, P _S (k) is a permutation sequence of a serving cell. The signal is then combined through a repetition combiner 311 to form Equation 11 below.

At this time, the MSE (Mean Squared Error) of the signal input to the Symbol Demapper may be expressed as Equation 12 below.

The relationship between the CINR obtained from Equation 7 and the MSE obtained from Equation 12 can be seen as shown in Equation 13 when the assumptions used in Equation 7 are applied.

FIG. 4 is a diagram illustrating an example of a frame structure of an OFDMA system using a time division duplexing (TDD) scheme.

Referring to FIG. 4, in the frame, the vertical axis 401 represents a frequency band of a subcarrier, and the horizontal axis 403 represents a time axis with an OFDMA symbol. As shown in the figure, it can be seen that a downlink (DL) 410 section and an uplink (UL) 430 section are separated in time. The first symbol of the downlink frame is a preamble 411. The terminal uses the preamble 411 to acquire synchronization, base station ID acquisition, channel estimation, and the like. Since the base station ID is used as a seed value of scrambling, subcarrier permutation, and the like, the DL data bursts 419, 421, 423, 425, and 427 are decoded. In order to achieve this, it is necessary to acquire a base station identifier (BSID). The Preamble 411 is followed by a Frame Control Header (FCH) 413, which contains information necessary for decoding the DL-MAP 415. In other words, the FCH 413 contains contents such as a DL-MAP length, a coding scheme of the DL-MAP, and the like. The DL-MAP 415 contains information necessary for DL data burst decoding of this frame. That is, the location and size information of each burst, Modulation and Coding Scheme (MCS) information of bursts, etc. are included, and thus DL data bursts (417, 419, 421, 423). In order to decode 425, the signal is processed as shown in FIG. 5.

5 is a flowchart illustrating a signal processing procedure for DL burst decoding of an OFDMA receiver. As shown in FIG. 5, the receiver acquires a base station ID (Base Station: BS) based on the preamble (501), and decodes the FCH corresponding to the obtained base station ID (503). The corresponding DL MAP is decoded using the DL MAP decoding information present in the MAP. (505) The DL bursts are identified from the DL MAP and the DL bursts are decoded by identifying the positions of the DL bursts 417, 419, 421, 423, and 425. .

In order to remove an interference signal in such an OFDMA system, first, an interference signal is correctly detected and a series of signal processing are performed to regenerate the detected interference signal into a transmission signal type and regenerate it from the received signal. The process is necessary.

The most suitable to apply this interference cancellation scheme is the DL-MAP (415). Since the DL-MAP 415 comes from the same base station at all base stations, the interference between the base stations is the most severe, which is the biggest cause of the deterioration of handover performance. The key to the interference cancellation technique is to correctly detect the interference signal. The DL-MAP 415 is generally modulated by QPSK and repetition coding is applied, so that it is easy to detect the interference signal. In addition, since the DL-MAP 415 immediately follows the preamble signal 411 having less influence of the interference signal in time, the channel estimation of the interference signal using the preamble signal is also easy. .

In the following description, an embodiment of the present invention describes a structure of a receiver to which an interference signal cancellation technique is applied to effectively remove an interference signal and thus improves the reception performance of the receiver. In addition, a description will be given of the signal processing process and conditions that can improve the handover performance by correctly applying the interference cancellation technique during handover.

6 is a block diagram showing a receiver 600 in an OFDMA system according to a first preferred embodiment of the present invention. A first embodiment of the present invention is a structure that improves reception performance by generating an interference signal for a received signal by subtracting the received signal by applying FEC. That is, a method of decoding up to DL bursts of an interference signal will be hereinafter referred to as an FEC method.

Referring to FIG. 6, the receiver 600 of the present embodiment includes a control unit 610 for controlling each functional block to use the FEC method of the present invention, and an interference signal canceller 630 for regenerating an interference signal using the FEC method. ) Is configured.

Since the reception process from the serving base station in the present embodiment has been described above, the control unit 610 and the interference signal canceller 630 of the present invention will be mainly described. The receiver 600 includes an interference signal canceller 630 for regenerating an interference signal received in addition to a general reception block, and a subtractor for subtracting a signal regenerated from the interference signal canceller 630 from a signal of a base station currently being received. 603, a switching unit 643 for switching the subtraction or not, and a control unit 610 for controlling whether or not the signal regenerated from the interference signal canceller 630 is used and for each of the functional blocks. Regenerating an interference signal in the present invention means generating the same signal as that of the transmitter of the interference signal.

Looking at the receiver 600 in detail, the control unit 610 first detects the interference signal using the neighbor base station ID causing the interference in order to detect the interference signal. Here, the interference signal is detected by a CINR meter (not shown). The controller 610 controls the interference signal canceller 630 and the switching unit 643 when a predetermined condition is satisfied by measuring interference signals of neighboring base stations from the CINR measuring instrument.

When the control unit 630 receives the interference signal from the neighbor base stations more than a predetermined threshold, the control unit receives the interference signal of the base station. The method for detecting an interference signal that becomes the interference signal is performed in the same manner as the OFDMA receiver as described with reference to FIG. 3. That is, the received signal is transmitted through the descrambler 605, the channel estimator 607, the channel compensator 609, the subcarrier ordering 611, the iterator combiner 613, the symbol demapper 615, and the FEC decoder 617. Detect.

The interference signal canceller 630 regenerates the interference signal transmitted through the channel by using the interference signal detected from the receiver. Regenerating the interference signal means generating the same as the transmission signal. The order of regenerating the interference signal follows the scheme generated in the OFDMA transmitter as shown in FIG. Accordingly, the interference signal canceller 630 includes an FEC encoder 631, a symbol mapper 633, an iterator 635, a subcarrier permuter 637, a scrambler 639, and a multiplier 641. That is, the method for generating the interference signal is subjected to FEC encoding, symbol mapping, repetition coding, subcarrier permutation, and scrambling.

The multiplier 641 multiplies the generated interference signal by the channel estimation result of the channel estimator 607. Then, the interference signal received through the channel can be obtained. When the regenerated interference signal is finally subtracted from the received signal, a clean signal from which the interference signal has been removed can be obtained. The receiver 600 of the present invention may detect its own signal by using the serving cell base station ID again using the received signal from which the interference signal has been removed. The controller 610 controls the flow of these signals. That is, when detecting or regenerating the interference signal, the base station ID of the interference signal is provided to the scrambler 639, the descrambler 605, the subcarrier permuter 637, and the subchannel allocator 611 to detect its own signal. In doing so, the base station ID to which the base station belongs is provided to the blocks.

7 is a block diagram illustrating a receiver 700 in an OFDMA system in accordance with a second preferred embodiment of the present invention. Although the first embodiment has an advantage of detecting a more accurate interference signal through the FEC, the time delay to remove the interference signal is large because the time delay and complexity of the FEC decoder 617 are larger than those of the other blocks. It has the disadvantage of greatly increasing latency and complexity. It's a bit less powerful, but it's a way to greatly reduce latency and complexity. It should be noted that the same apparatus described above in the following description uses the same reference numerals.

Referring to FIG. 7, the receiver 700 includes an interference signal canceller 730 for regenerating interference signals other than a general reception block, and a base station currently receiving a signal regenerated from the interference signal canceller 730. A subtractor 703 for subtracting the signal of the signal, a switching unit 743 for switching the subtraction or not, and a control unit 710 for controlling the use of the interference signal regenerated from the interference signal canceller 730 and the respective functional blocks. ) Is configured.

Unlike the FEC method, the interference signal canceller 730 of the receiver 700 does not include the FEC encoder 631 and the symbol mapper 633, and includes a slicer 731, an iterator 733, and a subcarrier allocator ( 735, a scrambler 737, and a multiplier 741. The slicer 731 performs a series of processes, such as symbol demapping and mapping, by using the signal repeatedly coupled from the repeating combiner 613. That is, in case of QPSK symbol, symbol mapping is performed by judging only the Sing Bit of I axis and Q side. For example, when a repetitively coupled signal (0.2, -1.3) comes in, it is mapped to (1.0, -1.0) after slicing. Accordingly, the signal interferer 730 regenerates the interference signal by using the received signal, thereby eliminating Log Likelyhood Ratio (LLR) calculation and FEC decoding. That is, a method of regenerating only an interference signal using a repetition combined signal. This method has the disadvantage of losing the CINR gain as much as FEC decoding, but has the advantage of greatly reducing the complexity and the latency. In the following description, this method will be referred to as a slicer method.

8 is a block diagram showing a receiver 800 according to a third preferred embodiment of the present invention.

Referring to FIG. 8, the receiver 800 of the present embodiment combines the FEC method and the slicer method. That is, since the interference signal canceller 830 uses the FEC method and the slicer method in combination, the interference signal canceller 830 includes all the building blocks of the signal interferer of FIGS. 6 and 7. The receiver 800 has switching sections 805, 807, 809 for switching the signal path to control this approach. The control unit 810 measures the CINR of the signals of neighboring base stations to pass through the slicer 835 if it is above a certain threshold value, otherwise regenerates the interference signal through the FEC encoder 831. Accordingly, when the CINR of the interference signal is large, there is almost no error in the constellation of the signal passing through the slicer 835, and thus there is little performance difference between the FEC method and the slicer method. Therefore, this embodiment can use only the advantages of the FEC method and the slicer method. Detailed operation of the receiver 800 will be omitted in the following description because it will be described later.

Next, the operation performed in the receiver of the embodiments of the present invention will be described with reference to FIG. 9.

9 is a flowchart illustrating a signal processing procedure in a receiver according to the present invention, which illustrates a process of generating an interference signal from a received signal. In the flowchart, the same as the receivers of the first and second embodiments are shown.

Referring to FIG. 9, first, in step 901, a receiver scans an ID of a neighbor BS that is causing interference in order to remove an interference signal, and measures a CINR value corresponding to the base station ID. . Here, the CINR measurement value uses a CINR measurement device that is provided in advance. Thereafter, in step 903, the receiver compares the measured CINR values of the neighboring base stations with the CINR values of the serving base station (Serving BS), and then compares the CINRs of the serving base station and the neighboring base stations. do. Here, the comparison method may include a method of comparing a difference between two CINRs with a predetermined threshold or determining whether the CINR of each neighboring base station is greater than a predetermined threshold. In step 905, the receiver selects neighboring base stations whose comparison result satisfies a predetermined condition. The base station satisfying the predetermined condition indicates neighboring base stations with severe interference.

Then, in step 907, the receiver selects the base station having the largest CINR to perform the removal from the interference base station signal with severe interference among the selected base stations. The reason why the interference signal is removed from the base station signal is that interference interference is easier than detection of weak signal. In step 907, when the interference signal is selected, the signal of the base station is decoded. The decoded interference signal is regenerated by the interference signal canceller in step 911. Then, in step 913, the receiver subtracts the generated interference signal from the received signal of the serving base station by a subtractor to perform the process of removing the interference signal. In this case, the reconstruction and removal of the interference signal may be performed by regenerating and removing the signal after FEC decoding as in the FEC method, and by regenerating and repeatedly repeating the combined signal as in the slicer method.

The receiver removing the strongest interference signal checks whether the interference signal removal is completed in step 915. The method of checking whether the interference signal removal is completed is a case where there is a base station satisfying a predetermined condition in step 905. Therefore, if the interference signal removal is not completed, steps 909 to 913 are repeated to remove the interference signal of the base station next to the removed interference signal. If all interference signals are removed from the received signal of the serving base station currently serving, the receiver decodes the signal of the serving base station serving the self in step 917.

Here, the decoding order of the interference signal is performed in the order of FCH, DL-MAP, DL burst, and the regeneration order of the interference signal is performed in the order of FCH, DL-MAP, DL burst. However, since it is difficult to decode all the FCH and DL-MAP portions of the interfering base station to remove the DL burst of the interfering signal, it is also possible to use only the DL-MAP to remove the interfering signal. Even in this case, the FCH must be decoded. However, since the FCH has a relatively small amount of information, decoding is not too much. For example, in IEEE802.16, the FCH consists of 24 bits. DL-MAP generally has a low Modulation and Coding Scheme (MCS) level (QPSK, 1/2 coding). In addition, since repetition coding has a maximum of 6 times and is immediately adjacent to a preamble in time, channel estimation is less affected by an interference signal. As a result, DL-MAP interference signals can be easily regenerated, resulting in excellent performance of the interference canceller.

The interference signal canceller according to the present invention can be used very effectively during handover.

10 is a graph showing the change in the CINR strength of the serving base station and the target base station according to the distance during handover. The horizontal axis of the graph represents a distance between a portable subscriber station (PSS) and a base station, and the vertical axis represents CINR strength.

As shown in FIG. 10, a handover occurs when a terminal moves from a serving base station (1001) to a target base station (1001) near a cell boundary, and thus a serving base station (Serving BS) CINR values of the 1001 and the target BS 1003 show a change with distance. The point at which a handover start is the difference between the CINR (CINRs) of the target base station 1003, CINR (CINRt) of the serving base station 1003 is started at the point becomes smaller than _{T U (Upper Threshold) (1005} ). The point where the handover is completed is completed at the point where the difference between CINRt and CINRs becomes larger than the lower threshold (100 _L ). That is, when the handover occurs, the following Equation 14 is as follows.

Since the target base station 1003 provides a large interference signal at the time when such a handover occurs, the reception performance of the terminal is degraded, and it is very effective to use the interference signal canceller according to the present invention. Therefore, the predetermined threshold value used in the control unit of the interference signal canceller of the present invention finds and applies an optimal value in consideration of the handover condition.

Next, a process of removing the interference signal according to the present invention during handover will be described with reference to FIG. 11.

FIG. 11 is a flowchart illustrating a process of removing an interference signal of a target base station 1003 which is an interfering base station during handover in a terminal.

보다 큰 경우인지 확인하는 조건이다. 상기 1103단계에서의 조건을 만족하지 않으면, 1115단계로 진행하여 서빙 기지국(1001)의 신호를 수신한다. 그러나 상기 1103단계에서의 조건을 만족하게 되면, 단말기는 1105단계에서 상기 타겟 기지국의 FCH를 디코딩한다. 왜냐하면 FCH를 먼저 디코딩 해야 그 다음에오는 DL-MAP의 길이를 알 수 있기 때문입니다. 즉 간섭기지국의 DL-MAP 길이와 서빙 기지국의 DL-MAP의 길이가 서로 다른 경우, 간섭 신호를 제거시 간섭 기지국의 DL-MAP 길이만큼만 빼 주어야하기 때문이다.Referring to FIG. 11, in step 1101, the terminal measures CINR values of the serving base station 1001 and the target base station 1003, which is an interfering base station. Then, in step 1103, it is checked whether the predetermined condition according to Equation 14 and the present invention is satisfied. The predetermined condition according to the present invention is that the CINR of the target base station 1003 is the minimum threshold value.

Condition to check if greater than If the condition in step 1103 is not satisfied, the process proceeds to step 1115 to receive a signal from the serving base station 1001. However, if the condition in step 1103 is satisfied, the terminal decodes the FCH of the target base station in step 1105. This is because the FCH must be decoded first to know the length of the DL-MAP that follows. That is, when the length of the DL-MAP of the interfering base station and the length of the DL-MAP of the serving base station are different, it is necessary to subtract only the DL-MAP length of the interfering base station when removing the interference signal.

값이상인지 확인한다. 여기서 상기 조건을 확인하는 이유는 본 발명의 제 3실시예에 따라 간섭 신호를 제거시 FCE 방법과 슬라이서 방법을 선택하기 위함이다. 따라서 상기 CINRt가

이상인 경우 1111단계로 진행하여 슬라이서 방법을 이용하여 타겟 기지국(1003)의 FCH와 DL-MAP을 재생성하고, CINRt가

이하인 경우 FEC 방법을 이용하여 타겟 기지국(1003)의 FCH와 DL-MAP을 재생성한다. 왜냐하면 간섭신호의 CINR이

이상인 큰 경우에는 슬라이서 방법과 FEC 방법의 성능 차이가 거의 없기 때문에, 시간 지연(Latency)을 줄이기 위해 슬라이서 방법을 선택한다.Then, in step 1107, the terminal determines that the CINR (CINRt) of the target base station is

Check if the value is over. The reason for checking the condition is to select the FCE method and the slicer method when removing the interference signal according to the third embodiment of the present invention. Therefore, the CINRt is

If it is above, proceed to step 1111 to regenerate the FCH and DL-MAP of the target base station 1003 using the slicer method, CINRt is

In the following case, the FCH and DL-MAP of the target base station 1003 are regenerated using the FEC method. Because the CINR of the interfering signal

In the larger case, since there is almost no difference in performance between the slicer method and the FEC method, the slicer method is selected to reduce the latency.

When the interference signal of the target base station 1003 is regenerated, the terminal removes the reproduced interference signal from the received signal of the serving base station 1001 in step 1113 and receives the signal of the serving base station 1001 in step 1115.

Next, the reception performance of the conventional terminal in the OFDMA system and the terminal according to the embodiments of the present invention will be described using the graph shown in FIG. In the present experiment, a conventional terminal 1201, an IC with Slicer 1203 using an interference canceller using the slicer method, and an IC with FEC using an interference canceller using the FEC method ( 1205). Here, the horizontal axis represents the strength of the CINR of the serving base station, and the vertical axis represents the mean squared error (MSE). The condition of the experimental result is that when there is only one interfering base station, the channel is AWGN (Additive White Gaussian Noise), the signal-to-noise ratio except the interference signal is 6dB, the modulation method is QPSK, and the repetition coding is 6 to be. It is assumed that the reproducibility of the interference signal is perfect except channel estimation.

Referring to the graph of FIG. 12, it can be seen that the receiver according to the present invention generally has better performance than the conventional receiver because the MSE value is lowered when the CINR of the serving base station is weakened. In the conventional OFDMA receiver 1201, as the CINR of the received signal decreases, that is, the strength of the interference signal increases, the MSE value increases linearly. In the case of using the interference canceller (1203, 1205), the performance is worse than that of the conventional receiver in the high CINR portion. This is because the high CINR portion has a weak interference signal, so the interference signal detection performance is deteriorated. By subtracting the regenerated interference signal, the performance is rather bad. On the contrary, in the region with low CINR, the interference signal has a relatively large strength, so that the regeneration of the interference signal is perfect and the performance is excellent. In this experiment, the signal-to-noise ratio excluding the interference signal was 6dB and the repetition coding was applied six times. Therefore, the theoretical minimum value of MSE is given by Equation 15 below.

As shown in FIG. 12, it can be seen that the interference signal canceller approaches the MSE minimum value in the low CINR portion.

The performance of the interference canceller is better because the signal-to-interference ratio (SIR) is lower, that is, the larger the interference signal of the interfering base station, the better the performance is. The threshold value should be determined to determine the time point at which the interference canceller is used, as shown in Fig. 12, the point at which the performance of the interference canceller is equal to that of the interference canceller is not equal to that of the interference canceller. For example, in the case of the interference signal canceller 1203 using the slicer method, the threshold may be set to 3 dB, and in the case of the interference signal canceller 1205 using the FEC method, the threshold may be set to 4 dB.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, the present invention eliminates interference signals generated from neighboring base stations, and thus can not only improve the reception performance of the terminal but also improve the performance of handover.

Claims (11)

What is claimed is: 1. A method of canceling an interference signal in a receiver of an orthogonal frequency division multiple access (OFDMA) system, Measuring a carrier to interference noise ratio (CINR) of a neighboring base station and selecting interference signals whose difference between the CINR of the serving base station and the measured CINR of the neighboring base station satisfies a predetermined threshold value; 1 course, A second process of selecting and detecting the selected interference signals; Regenerating the detected interference signal; And a fourth process of removing the regenerated interference signal from a signal of a serving base station. The method of claim 1, wherein the interference signal in the first process, The interference signal removing method characterized in that the identification using the base station identifier (BSID) of the neighboring base station. The method of claim 1, wherein the second process comprises: Determining the interference signal in the largest order of the interference signal, Receiving the determined interference signal and performing channel compensation; Converting the channel compensated interference signal into a subchannel form by a constant permutation rule; And interfering with the interference signal converted into the subchannels. The method of claim 3, wherein Demapping the repeatedly coupled interference signal; And performing forward error correction (FEC decoding) on the demapped signal. The method of claim 4, The FEC decoding method performs up to a forward channel (FCH) and downlink information (Downlink-MAP: DL-MAP). The method of claim 4, wherein The FEC decoding process includes performing a forward channel (FCH), downlink information (Downlink-MAP: DL-MAP), and downlink burst. The method of claim 3, wherein the third process, Repeating the mapped interference signal a predetermined number of times; Mixing the repeated interference signal in the form of subcarriers, Scrambling an interference signal mixed with the subcarriers; And multiplying the scrambled interference signal with the channel estimated signal. The method of claim 4, wherein the third process, Detecting, encoding and mapping the decoded interference signal; Repeating the mapped interference signal a predetermined number of times; Mixing the repeated interference signal in the form of subcarriers, Scrambling the interference signal of the subcarrier type; And multiplying the scrambled interference signal with the channel estimated signal. In the receiver of an Orthogonal Frequency Division Multiple Access (OFDMA) system, A receiver which receives and processes a signal transmitted from a base station, An interference signal canceller for regenerating an interference signal received by the receiver when a difference between a carrier to interference noise ratio (CINR) of a serving base station and a CINR of a neighboring base station satisfies a predetermined threshold value; A multiplier for multiplying the regenerated interference signal with a channel estimated signal value; A subtractor for removing the multiplied signal from the signal of the serving base station; And a controller configured to control the operation of the interference signal canceller by determining the interference signal in the largest order of the interference signal. 10. The method of claim 9, wherein the signal interference canceller, An encoder for detecting and encoding the interference signal decoded from the receiving unit; A symbol mapper for mapping the encoded interference signal; A repeater for repeating the mapped interference signal a predetermined number of times; A subcarrier allocator for mixing the repeated interference signals into subcarriers according to a constant permutation rule; A scrambler for scrambling the interference signal of the subcarrier type; And a multiplier configured to multiply the scrambled interference signal with a channel estimated signal by the receiver. The method of claim 9, wherein the interference signal canceller, A slicer for detecting an interference signal repeatedly coupled from the receiver; A repeater for repeating the detected interference signal a predetermined number of times; A subcarrier allocator for mixing the repeated interference signals into subcarriers according to a constant permutation rule; A scrambler for scrambling the interference signal of the subcarrier type; And a multiplier configured to multiply the scrambled interference signal with a channel estimated signal by the receiver.

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