KR20080088765A - An method and apparatus for decreasing interference of cells in an communication system - Google Patents

Abstract

A method and an apparatus for reducing inter-cell interference in a communication system are provided to increase the frequency reuse rate at a cell boundary and improve system performance by applying an erasure coding scheme in order to reduce errors in data transmission in a range which a common channel cannot be decoded in. An MS(Mobile Station) receives neighbor cell search information from neighbor cells(200). Based on the neighbor cell search information, the MS judges whether neighbor cell searching is possible(202). If so, the MS confirms whether it is possible to decode the common channels of the neighbor cells(204). If so, the MS determines whether to estimate the whole band channels of the neighbor cells or to use the average channel gain(206). In case it is possible to estimate the whole band channels of the neighbor cells, the MS estimates the whole band channels of the neighbor cells and calculates the power of interference signals(210). Then the MS calculates the LLR(Likelihood Ratio) based on the estimated channel values and noise distribution values(220).

Description

Method and apparatus for reducing inter-cell interference in a communication system {An method and Apparatus for Decreasing interference of cells In An Communication System}

1 is a block diagram of a terminal according to an embodiment of the present invention.

2 is a flowchart illustrating an operation of a terminal according to an exemplary embodiment of the present invention.

3 is a block diagram of a transmitter according to a preferred embodiment of the present invention.

4 is a frequency layout arranged for each cell according to a preferred embodiment of the present invention.

5a and b are diagrams showing the performance effect according to a preferred embodiment of the present invention.

The present invention is directed to reducing interference between cells in a communication system, and more particularly, to an adaptive decoding method and apparatus.

Orthogonal Frequency Division Multiplex (hereinafter, referred to as 'OFDM') modulation scheme is a communication scheme that prevents interference between channels using a plurality of subcarriers having mutual orthogonality. However, when the user terminal is in violation of a plurality of cells, interference occurs between channels used by each of the cells. Therefore, there has been a need for a technique for removing inter-cell interference.

There are the following methods to remove the inter-cell interference phenomenon.

First, as a differential subchannel allocation method, when a subchannel allocation request is received from a plurality of base stations, the subchannel is differentially allocated according to the position of the user terminal. That is, as the service area in the home cell to which the user terminal belongs is closer to the base station, the frequency reuse rate is increased by allocating subchannels first. In this case, since the frequency reuse rate is distributed according to the position of the user terminal, the frequency reuse efficiency is lowered at the cell boundary, thereby reducing the overall system capacity.

Next, when combining OFDM and frequency hopping, a different frequency hopping pattern is used for each cell so that one channel of a corresponding cell uniformly collides with several channels of another cell. In other words, by increasing the frequency utilization rate by averaging the inter-cell interference, the frequency hopping pattern is divided so that collisions occur as evenly as possible with all resource sets in the resource spaces in other adjacent cells. In this case, when a plurality of user terminals exist at a cell boundary, there is a problem that it is difficult to guarantee the quality of service (QoS) of the user.

Accordingly, an object of the present invention, which was devised to solve the problems of the prior art operating as described above, provides a method and apparatus for increasing a transmission rate and a frequency reuse rate in order to provide a better service to a terminal located at a cell boundary. will be.

Another object of the present invention is to provide a method and apparatus for adaptive decoding in order to effectively mitigate interference at a cell boundary according to the degree of neighbor cell information acquired by a terminal.

The method according to the embodiment of the present invention, which is designed to achieve the above object, in the communication system, in the decoding method for reducing the interference between cells,

Acquiring the interference information of the neighbor cells by a terminal located at a boundary between the home cell and neighbor cells to which the terminal belongs;

And upon receiving data from the home cell, adaptively decoding the received data according to interference information of the neighbor cells.

An apparatus according to an embodiment of the present invention, in the communication system, in the decoding device for reducing the interference between cells,

A neighboring cell searcher for acquiring interference information of the neighboring cells by a terminal located at a boundary between a home cell and neighboring cells to which the terminal belongs;

And a channel estimator for adaptively decoding the received data according to interference information of the neighbor cells when receiving data from the home cell.

According to another aspect of the present invention, there is provided a transmission apparatus in a communication system.

A control channel generator for generating a common channel including transmission power information of each of the subcarriers of each data subchannel;

And a frame configurator arranged on the time and frequency axes within each frame such that the common channel and the user-specific data channel do not overlap adjacent cells according to frame configuration information.

Hereinafter, with reference to the accompanying drawings will be described in detail the operating principle of the preferred embodiment of the present invention. Like reference numerals are used to designate like elements even though they are shown in different drawings, and detailed descriptions of related well-known functions or configurations are not required to describe the present invention. If it is determined that it can be blurred, the detailed description thereof will be omitted. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the specification.

The present invention provides a process of searching for neighbor cells of a home cell in which a terminal is located, decoding a common channel containing transmission power information of each of subcarriers constituting a subchannel in the neighbor cell, and Estimating a channel, selecting a method of decoding data serviced from a home cell, and decoding.

Hereinafter, it is assumed that the present invention uses a conventional log likelihood ratio-based decoder through reliability spread such as a turbo code or a low density parity check (LDPC) code. In addition, it is assumed that subcarriers constituting one subchannel in one cell are evenly spread over all subchannels of another adjacent cell by using different subchannel methods for neighboring cells of a cell where the user terminal is located.

1 is a block diagram of a terminal according to an embodiment of the present invention.

Referring to FIG. 1, a terminal 100 located at a boundary of a plurality of cells includes an adjacent cell searcher 102, a decoding method determiner 104, a channel estimator 106, a decoder 108, and a log likelihood ratio ( Likelihood ratio, hereinafter referred to as 'LLR').

The neighbor cell searcher 102 searches for neighbor cells of a home cell serviced by the terminal to determine the number and size of the neighbor cells, and forms a subcarrier in a subchannel through common channel decoding of the neighbor cells. Obtain power transmission information of and transmit it to the decoding method determiner 104.

The decoding method determiner 104 selects a decoding method according to the common channel decoding result, generates decoding mode information indicating the selected decoding method, and transmits the decoding mode information to the channel estimator 106. The decoding method will be described later in detail.

The channel estimator 104 estimates a channel of an adjacent cell according to the received decoding mode information to generate a channel value, and then transfers the channel value to the decoder 108.

The decoder 108 calculates the interference and noise variance of the neighboring cell according to the selected decoding method using the channel value and transmits the interference and noise variance to the log likelihood ratio calculator 110. The log likelihood ratio calculator 110 calculates a log likelihood ratio using the channel estimation value of the home cell of the terminal 100 and the interference and noise calculation of the received neighbor cell, and transmits the log likelihood ratio to the decoder 108.

The decoder 108 then decodes the data symbols received from the home cell through the estimated channel estimate and log likelihood ratio as described above.

There are three decoding methods selected by the decoding method determiner 104 according to the common channel decoding result.

First, the first decoding method and the second decoding method are selected when the common channel decoding is possible, and are classified according to the method of estimating the channel.

)을 하기 <수학식 1>과 같이 계산한다.In a first decoding method, a terminal located at a cell boundary decodes a common channel partial signal in a corresponding frame of an adjacent cell to obtain power information allocated to each subcarrier of each cell base station. In addition, the terminal uses the channel information estimated through the pilot and the obtained power information through the log likelihood ratio-based decoder, the interference power of the l-th subcarrier (

) Is calculated as in Equation 1 below.

는 l번째 부반송파에서 단말과 인접 셀 사이의 채널 추정값이고, 상기

는 해당 부반송파에 인접 셀이 송신한 전력이고, 상기

은 잡음의 분산이다.Where

Is a channel estimate value between the UE and the neighbor cell in the l-th subcarrier,

Is the power transmitted by the neighbor cell to the subcarrier,

Is the variance of noise.

)을 하기 <수학식 2>와 같이 계산한다.In a second decoding method, a UE located at a cell boundary decodes a common channel in a corresponding frame of an adjacent cell to obtain transmit power information for each subcarrier constituting a subchannel, and receives a preamble or pilot of the neighbor cell. The average channel gain is obtained, and the interference power of the l th subcarrier through the log likelihood ratio based decoder

) Is calculated as in Equation 2 below.

는 단말과 인접 셀 사이 전 주파수 대역의 평균이득이고, 상기

는 해당 부반송파에 인접 셀이 송신한 전력이고, 상기

은 잡음의 분산이다.Where

Is the average gain of all frequency bands between the terminal and the neighboring cell.

Is the power transmitted by the neighbor cell to the subcarrier,

Is the variance of noise.

)을 하기 <수학식 3>와 같이 계산한다.The third decoding method is used when the neighbor cell searcher 102 fails to acquire the information of the neighbor cells by failing to search the neighbor cell or to decode the common channel, and is called an erasure deciding method. The erasure decoding scheme uses a threshold value of data symbol powers received by the UE from a home cell.

) Is calculated as in Equation 3 below.

은 l번째 수신신호이고,

은 l번째 추정된 신호의 채널 정보이고,

는 성능의 범위를 저하시키지 않게 하는 적절한 상수값이다. Here, L is the total number of signals received by the terminal,

Is the l-th received signal,

Is channel information of the l-th estimated signal,

Is an appropriate constant value that does not degrade the range of performance.

는 하기 <수학식 4>와 같이 계산된다.remind,

Is calculated as in Equation 4 below.

과 홈 셀의 부채널의 l번째 데이터 심볼의 수신전력을 비교하여, 상기 l번째 심볼의 수신전력이 상기

보다 클 경우, 상기 심볼은 많은 간섭 성분이 있다고 판단하여 해당 심볼의 로그 우도비를 0으로 세팅(setting)한다.Thereafter, the terminal is the

And the received power of the l-th data symbol of the sub-channel of the home cell, so that the received power of the l-th symbol is

If larger, the symbol determines that there are many interference components and sets the log likelihood ratio of the symbol to zero.

보다 작거나 같은 데이터 심볼들에 대해서만 잡음의 크기(

)를 하기 <수학식 5>과 같이 계산한다. The terminal of the data symbols received from the home cell, the

The magnitude of the noise only for data symbols that are less than or equal to

) Is calculated as in Equation 5 below.

은 set U에 속하는 l번째 수신신호이고,

은 set U에서 l번째 속하는 수신신호의 채널 추정값이다.Here, when the set of received data less than or equal to the threshold is set U, the U is the number of received data belonging to set U,

Is the l-th received signal belonging to set U,

Is the channel estimate of the received signal belonging to the l th set in U.

That is, according to the present invention, the common channel and the adjacent channel of the home cell are shared by using the power of the subcarriers constituting the subchannel of the cell through the common channel decoding process of the home cell and the neighbor cell to which the corresponding UE belongs. The range of the signal-to-interference noise ratio that enables decoding of the channel is determined. Thereafter, the terminal acquires neighbor cell search information, determines one of the first or second decoding schemes within the range according to the neighbor cell search information, and estimates power information of an interference signal transmitted from the neighbor cell. Calculate the log likelihood ratio. If the common channel decoding through the neighbor cell search is failed because the signal-to-interference noise ratio is out of range, the log likelihood ratio is removed after the signals below the threshold, that is, the interference signals are removed by using a third decoding method. Calculate

In addition, by setting the range in which the common channel having the subchannel power information of the neighbor cells can be decoded as wide as possible, the first and second decoding schemes should be selected as a method of decoding the data signal received by the terminal. That is, the decoding performance of the common channel should be higher than that of decoding the data channel by the third decoding method. In this case, even when the data channels cannot use the third decoding method, the common channel can use the third decoding method. In addition, since the data channels are successfully decoded through the first or second decoding method, the performance at the cell boundary is increased.

On the other hand, in order to improve the performance of the common channel including the subchannel information of the neighbor cell, the performance can be further improved by varying the frequency reuse rate of the section in which the common channel is transmitted and the section in which the data is transmitted.

2 is a flowchart illustrating operations of a terminal according to an exemplary embodiment of the present invention.

Referring to FIG. 2, in step 200, the terminal receives neighbor cell search information from neighbor cells of a home cell to which the terminal belongs, and proceeds to step 202. The neighbor cell search information includes a search signal of each neighbor cell, common channel decoding result information of the neighbor cell, and transmission power of each subcarrier belonging to the corresponding subchannel obtained through the neighbor cell pilot. Then, it is determined whether to estimate the channel of all frequency bands or calculate only the average channel gain within the signal-to-interference noise ratio range where the common channel of the home cell and the neighbor cell of the terminal are decoded according to the obtained transmission power. A decoding mode control signal is generated.

In step 202, the terminal determines whether the neighbor cell can be searched through the neighbor cell search information. If the determination result is not possible, the process proceeds to step 208. If the determination result is possible, in step 204, it is checked whether the common channel of the corresponding neighbor cell is decodable. That is, the decoding mode control signal, the terminal is determined using the transmission power to each of the subcarriers belonging to the subchannel of each cell received through the common channel from the neighbor cell search information.

If it is possible to decode the result of the check, in step 206, the terminal examines the decoding mode control signal to determine whether to estimate the full band channel of the adjacent cells or use the average channel gain.

If the channel of the full band of the adjacent cells is estimated in step 206, in step 210, the terminal estimates the frequency full-band channels of the adjacent cell to calculate the power of the interference signal as shown in Equation 1, Proceed to step 220.

If it is determined in step 206 to use the average channel gain of the neighbor cells, in step 212 the terminal obtains the average channel gain of the neighbor cells to calculate the power of the interference signal as shown in Equation 2, Proceed to step 220.

If the neighbor cell search is not possible in step 202, in step 208, the terminal calculates a threshold and noise variance using Equation 3 and Equation 4 according to an erasure decoding method. Proceed.

In step 214, the terminal compares whether the power of the received data symbol is greater than the threshold. If the comparison result is large, in step 216, the log likelihood ratio of the received data symbol is set to '0'. If the comparison result is less than or equal to, in step 218, the terminal recalculates the noise variance of the signals below the threshold, that is, the received signals not set to 0, as shown in Equation 5, and in step 220 Proceed to

In step 220, the terminal calculates the log likelihood ratio using the noise variance and the channel value calculated in step 210 or step 212 or step 218.

As described above, by adaptively applying the decoding method of the UE according to the acquisition information of the neighbor cell, it is possible to improve the performance of the system in a non-uniform system environment where some received signals are affected by large interference noise. Will be.

3 is a block diagram of a transmitter according to a preferred embodiment of the present invention.

Referring to FIG. 3, the transmitter includes a user-specific data generator 302, a control channel generator 304, a pilot generator, a frame configurator 308, and an OFDM modulator 310.

The user-specific data generator 302 receives data of each user terminal, modulation / coding information for each subchannel of the corresponding cell, and transmission power information of each of the subcarriers constituting the subchannel to receive a user data channel for the user terminal. After generating a, it passes to the frame configurator 308.

The control channel generator 304 receives modulation / coding information for each subchannel and configuration information of a frame, generates various control channels according to the frame configuration information, and transmits them to the frame constructor 308. The control channel includes a common channel including transmission power information of each of the subcarriers of each data subchannel.

The pilot generator 306 receives corresponding cell information, allocates a pilot channel for the UE to estimate channel information of the corresponding cell, and transmits the pilot channel to the frame configurator 308.

The frame configurator 308 arranges the received data channel, the control channel and the pilot channel on the time and frequency axis within each frame so that adjacent cells do not overlap with each other according to frame configuration information. Through OFDM modulation is transmitted to the terminal.

4 is a frequency diagram arranged for each cell according to a preferred embodiment of the present invention. Here, the case of the neighbor cell 1 and the neighbor cell 2 of any user terminal will be described as an example, but a plurality of neighbor cells may exist.

Referring to FIG. 4, there are N pilots (pilot 1 to pilot N, pilot 1 'to pilot N') in cell 1 and cell 2, respectively. The frame configurator 308 staggers each of pilots 1 through N in the cell 1 so as not to overlap with pilots 1 'through N' in the cell 2.

5A and 5B are diagrams showing a performance effect according to a preferred embodiment of the present invention.

Referring to FIGS. 5A and 5B, a pilot is a performance graph in the case of channel estimation of the entire frequency band of adjacent cells according to a first decoding scheme, and an average channel (Aver.CH) is a mean channel gain according to a second scheme. Performance graph when used.

 Eraser is a performance graph according to the third method, and 'NED' does not erase data symbols exceeding a threshold value, and the interference and noise values calculated by Equation 4 are inputted to the LLR input. 'NONE' is a performance graph that uses noise variance as LLR input value without considering interference signal of adjacent cell.

Here, 1 / M is a ratio of subchannels per cell allowed to be allocated to a cell boundary terminal using a high transmit power, and the rest is allocated to a terminal located inside the cell so that the frequency reuse rate is 1 so that every sub-cell is 1 for each cell. Using a channel, but only at the cell boundary, has an effect of 1 / M reuse.

It can be seen that the remaining graphs dealing with the interference of the neighboring cell show much higher performance than the graph of 'NONE' which is not considered of the neighboring cell at the cell boundary.

In addition, if the pilot is affected by noise during channel estimation, the performance is worse than that without noise in all decoding methods. For example, the 'Erasure' method has a relatively higher gain of 2/16 than 1 / M = 1/16. That is, when transmitting a pilot from the base station, it can be seen that the power of the pilot should consider the noise level.

일 경우, 인접 셀 탐색이 실패하거나 인접 셀의 부채널을 구성하는 부반송파들의 전력 정보를 가지고 있는 공통 채널의 복호가 실패한 경우, 1/M=1/16일때 SIN은 -2dB이다. 그러나, 공통 채널 복호를 성공한 경우, 'pilot'은 약 7dB SIN이득을 얻고, AVR.Ch'는 2dB의 SIN이득을 얻게 된다.If the target PER is

In this case, when discovery of a neighbor cell fails or decoding of a common channel having power information of subcarriers constituting a subchannel of the neighbor cell fails, SIN is -2 dB when 1 / M = 1/16. However, when the common channel decoding is successful, the pilot gains about 7dB SIN and AVR.Ch gains 2dB SIN.

일때 SIN-7dB에서 공통채널의 복호 성능이 얻어질 경우, 사용자 단말의 홈 셀과 인접 셀의 공통 채널 복호는 SIR[-5dB, 5dB]인 구간에서 성공할 수 있다. 1/M=1/16인 경우와 2/16인 모두 상기 구간에서 첫번째와 두번째 복호 방식에 의해 상기 목표 PER이

보다 적은 에러율을 얻을 수 있고, SIR 5dB이상인 구간에서도 세번째 복호방식'Erasure'에 의해서 상기 목표 PER이

보다 적은 에러율을 얻을 수 있다.For example, discovering adjacent cells is successful and PER is

When the decoding performance of the common channel is obtained at SIN-7dB, the common channel decoding of the home cell and the adjacent cell of the user terminal may be successful in the interval of SIR [-5dB, 5dB]. In both 1 / M = 1/16 and 2/16, the target PER is increased by the first and second decoding methods in the interval.

A lower error rate can be obtained, and the target PER is reduced by the third decoding method 'Erasure' even in a section where SIR is 5 dB or more.

Less error rate can be obtained.

That is, by using the adaptive decoding method proposed in the present invention, the terminal located in the cell boundary can perform communication with less error.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described. However, various modifications may be made 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 those equivalent to the scope of the claims.

In the present invention operating as described in detail above, the effects obtained by the representative ones of the disclosed inventions will be briefly described as follows.

According to the present invention, a UE located at a cell boundary uses a full-band channel estimation value within a signal-to-noise ratio range in which a home cell and a neighbor cell of the UE can be decoded by using transmission power of each subcarrier constituting a subchannel of a neighbor cell. Or, if decoding is performed using average values of channel estimates, there is an effect of increasing frequency reuse without increasing an error in data transmission. In addition, in the range where the common channel is not decoded, an error in data transmission is reduced through an erasure coding scheme, thereby improving system performance by increasing frequency reuse rate at a cell boundary.

Claims (23)

In the communication system, In the decoding method for reducing the interference between cells, Acquiring the interference information of the neighbor cells by a terminal located at a boundary between the home cell and the neighbor cells to which the terminal belongs; And when the data is received from the home cell, adaptively decoding the received data according to interference information of the neighbor cells. The method of claim 1, wherein the acquiring And determining whether the common channel including the transmission power of each of the subcarriers constituting the subchannel of the neighbor cell can be decoded. The method of claim 2, wherein the checking process comprises: Determining whether a full-band channel between the terminal and the neighbor cells is estimateable by using the pilot of the neighbor cell; Estimating an average channel gain between the terminal and the neighboring cell using a pilot of a neighboring cell if the full-band channel is not predictable. The method of claim 3, wherein the adaptive decoding process, If the full-band channel can be estimated, the full-band channel of the adjacent cell is estimated, and the interference power of the l th subcarrier (

The decoding method further comprises the step of calculating). Equation

Where

The channel estimate value between the UE and the neighbor cell in the l th subcarrier is

Is the power transmitted by the neighbor cell to the subcarrier,

Is the variance of noise. 5. The method of claim 4, further comprising: calculating a log likelihood ratio using the calculated subcarrier interference power and a full-band channel estimate value; And decoding the received data symbol through the load likelihood ratio. The method of claim 3, wherein the adaptive decoding process, Estimating the average channel gain, and using the estimated average channel gain, the interference power of the l-th subcarrier (

The decoding method further comprises the step of calculating). Equation

Where

Is the average gain of all frequency bands between the terminal and the neighboring cell.

Is the power transmitted by the neighbor cell to the subcarrier,

Is the variance of noise. The method of claim 6, further comprising: calculating a log likelihood ratio using the calculated subcarrier interference power and the obtained average channel gain; And decoding the received data symbol through the load likelihood ratio. The method of claim 2, Calculating a transmission power threshold value of the received data when decoding of the common channel is not possible; And comparing the calculated transmit power threshold with the transmit power of the received data and setting a log likelihood ratio of the received data having a transmit power larger than the threshold to zero. The method of claim 8, wherein the threshold value, The decoding method is characterized by the following equation. Equation

here, (

) Is the noise dispersion power,

Is channel information,

Is an appropriate constant value that does not degrade the range of performance. 10. The method of claim 9, wherein the noise dispersion power (R) for the received data that is less than or equal to the threshold value as

The decoding method further comprises the step of calculating). Equation

Here, when the set of received data less than or equal to the threshold is set U, the U is the number of received data belonging to set U,

Is the l-th received signal belonging to set U,

Is the channel estimate of the received signal belonging to the l th set in U. The method of claim 4, further comprising: calculating a log likelihood ratio using the calculated subcarrier interference power and a channel estimate; And decoding the received data symbol through the load likelihood ratio. A decoding system for reducing interference between cells in a communication system, A neighboring cell searcher for acquiring interference information of the neighboring cells by a terminal located at a boundary between a home cell and neighboring cells to which the terminal belongs; And a channel estimator for adaptively decoding the received data according to interference information of the neighbor cells when receiving data from the home cell. The method of claim 12, And a decoding method determiner for checking whether a common channel including transmission power of each of the subcarriers constituting the subchannel of the adjacent cell can be decoded. The method of claim 13, wherein the decoding method determiner, The pilot of the neighbor cell is used to determine whether the full-band channel between the terminal and the neighbor cells is estimateable, and if the full-band channel is not estimable, the average between the terminal and the neighbor cell is used by using a pilot of the neighbor cell. Estimating a channel gain. The method of claim 14, wherein the channel estimator, If the full-band channel can be estimated, the full-band channel of the adjacent cell is estimated, and the interference power of the l-th subcarrier (

The decoding device, characterized in that for calculating (). Equation

Where

The channel estimation value between the UE and the neighbor cell in the l th subcarrier is

Is the power transmitted by the neighbor cell to the subcarrier,

Is the variance of noise. The log likelihood ratio calculation unit of claim 15, further comprising: a log likelihood ratio calculation unit configured to calculate a log likelihood ratio using the calculated subcarrier interference power and a full channel estimate; And a decoder for decoding the received data symbol through the load likelihood ratio. 15. The method of claim 14, wherein the channel estimator is Estimating the average channel gain, and using the estimated average channel gain, the interference power of the l-th subcarrier (

The decoding device, characterized in that for calculating (). Equation

Where

Is the average gain of all frequency bands between the terminal and the neighboring cell.

Is the power transmitted by the neighbor cell to the subcarrier,

Is the variance of noise. The method of claim 17, A log likelihood ratio calculator configured to calculate a log likelihood ratio using the calculated subcarrier interference power and the obtained average channel gain; And a decoder for decoding the received data symbol through the load likelihood ratio. The method of claim 13, When decoding of the common channel is not possible, a transmission power threshold value of the received data is calculated, the calculated transmission power threshold value is compared with the transmission power of the reception data, and the reception data having a transmission power larger than the threshold value. And a log likelihood ratio calculator for setting a log likelihood ratio of zero to zero. The method of claim 19, wherein the threshold value, The decoding device as described in the following equation. Equation

here, (

) Is the noise dispersion power,

Is channel information,

Is an appropriate constant value that does not degrade the range of performance. The method of claim 20, wherein the channel estimator, For received data that is less than or equal to the threshold, the noise dispersion power (

The decoding device, characterized in that for calculating (). Equation

Here, when the set of received data less than or equal to the threshold is set U, the U is the number of received data belonging to set U,

Is the l-th received signal belonging to set U,

Is the channel estimate of the received signal belonging to the l th set in U. 22. The apparatus of claim 21, further comprising: a log likelihood ratio calculator for calculating a log likelihood ratio using the calculated subcarrier interference power and a channel estimate value; And a decoder for decoding the received data symbol through the load likelihood ratio. A communication system comprising: a transmission apparatus for reducing interference between cells; A control channel generator for generating a common channel including transmission power information of each of the subcarriers of each data subchannel; And a frame configurator configured to arrange the common channel and the user-specific data channel on a time and frequency axis within each frame so that adjacent cells do not overlap with each other according to frame configuration information.

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