KR20060119143A - Multiple input multiple output antenna apparatus in multi-cell environments and method thereof - Google Patents

Abstract

A multi-transceiving antenna device in a multi-cell environment and a method thereof are provided to determine transmission methods in consideration of the performance of both self cell and neighboring cells by using information only, which is realistically obtainable in the multi-cell environment, thereby reducing complexity. Each of the second units calculates the instant performance of self cell for transmission methods of each cell by using estimated channel reaction information and noise/interference signal correlation matrices(S10,S12). Each unit calculates the average performance of neighboring cells in accordance with the transmission methods of each cell for transmission power by using pre-stored information(S14). Each unit selects transmission methods in consideration of a value of the calculated instant performance of the self cells and a value of the average performance of the neighboring cells(S16). Each unit feeds back information on the selected transmission methods to the first units of the corresponding cells(S18).

Description

Multiple input multiple output antenna apparatus in multi-cell environments and method

1 is a block diagram of a multiple transmit and receive antenna device in a multi-cell environment according to an embodiment of the present invention;

2 is a flowchart illustrating a multiple transmit / receive antenna method in a multi-cell environment according to an embodiment of the present invention.

<Description of Symbols for Major Parts of Drawings>

10: high frequency processing unit 12: channel response information estimation unit

14: noise and interference signal correlation matrix estimator

16: transmit power determination unit 18: instantaneous performance calculation unit of its own cell

20: average performance calculation unit of adjacent cells 22: transmission method determination unit

24: feedback information transmitter 26: information recovery unit

50: feedback information receiving unit 52: demultiplexer

54: transmission method implementation unit 56: high frequency processing unit

100: receiver of i-th cell 200: transmitter of i-th cell

The present invention relates to a multiple transmit / receive antenna device and a method thereof in a multi-cell environment, and more particularly, to improve the performance of an entire system by selecting a transmission scheme that improves not only the performance of its own cell but also the performance of neighboring cells. The present invention relates to a multiple transmit / receive antenna device and a method thereof in a multi-cell environment.

In general, a wireless communication system using multiple transmit / receive antennas is a communication system developed to achieve a large bit rate within a limited bandwidth, by using multiple antennas at a transmitter / receiver and adopting an appropriate transmitter / receiver structure accordingly. To achieve the data rate. In this case, the transmitting unit can properly utilize the transmitting antenna by multiplying each item of the signal vector to be transmitted by each power allocation value and multiplying the signal vector multiplied by the power allocation value again by the transmitting antenna weight matrix.

In the conventional multiple transmit / receive antenna system, a technique of assuming a one-to-one wireless communication system composed of a pair of transmitter / receivers has been applied without considering the existence of other cells causing interference signals. A method for achieving maximum frequency efficiency in such a one-to-one communication is well known, which is obtained by using a Single Value Decomposion (SVD) channel response information matrix to obtain a transmit antenna weight matrix to remove interference between subchannels. It is a method of allocating transmit power to water-filling method of subchannel of. Incidentally, power allocation is to determine how to divide (allocate) this transmit power to each subchannel.

However, this method requires that both the transmitter and the receiver know the channel response information between the transmitter and the receiver. Therefore, it is necessary to feed back channel response information from the receiver to the transmitter or to feed back the transmit antenna weight matrix and the power allocation value calculated from the channel response information. However, since the amount of channel response information fed back from the receiver to the transmitter increases in proportion to the product of the number of transmitting antennas and receiving antennas, feeding back the channel response information may reduce channel efficiency.

Many researches have been made to overcome these disadvantages, and among them, there is a transmit antenna subset selection method of selecting a plurality of transmit antennas as a suboptimal method (R. Heath Jr. and A. Paulraj). , "Antenna Selection for Spatially Multiplexing Systems based on Minimum Error Rate," in IEEE Int. Conf. Commun. , Helsinky, Finland, June 2001, pp. 2276-2280. In this method, after selecting a combination of transmit antennas that achieves optimal performance using the channel response information matrix measured at the receiver, only the information indicating the combination of the selected antennas is fed back to the transmitter, and the transmitter is equal to the selected transmit antenna. Allocate transmit power. (So in this case, is assigned the same power only if the belong to the weighting matrix N _t is a fixed value in ㅧ N _t unitary matrix, the power assigned to the sub-channel, that is, set the corresponding transmission antenna selected portion value of the transmitting antenna, the You don't have to feed back both information.)

Unlike the one-to-one communication described above, in a multi-cell environment, since the cell not only interferes with signals from neighboring neighbor cells but also interferes with neighbor cells, an optimal transmission scheme (hereinafter, referred to as a transmission scheme) Denotes a method of utilizing the transmit antenna, which is determined by the transmit antenna weight matrix and the power allocation. For example, in the above-described transmission antenna subset selection method, when transmission power is fixed, it is generally advantageous to select many transmission antennas in order to improve the performance of its own cell. On the other hand, when a particular cell selects a large number of transmit antennas, the performance of neighboring cells is greatly degraded. Therefore, when a transmitter of a specific cell determines a transmission scheme to improve only the performance of its own cell, the performance of the entire system including all cells may be degraded.

Blum studied the performance when the transmission scheme was determined in consideration of the performance of the entire system in a multi-cell environment (S. Ye and RS Blum, "Optimized signaling for MIMO interference systems with feedback," IEEE Trans.Signal Processing , vol 51, no. 11, pp. 2839-2848, Nov. 2003.). (In the above paper, although the research was conducted in the multi-link environment, not the multi-cell environment, the cell structure of the cellular system can be regarded as the multi-cell environment in the multi-link environment.) Maximizing the sum of the frequency efficiencies of its own cells and neighboring cells, when all the channel response information from the receiver to the receiver of its own cell and the receiver of the neighboring cell are known, and the transmitter of each cell knows the transmission method of neighboring cells. The transmission method is determined. In this method, since the transmission scheme is determined considering the performance of other cells, the average frequency efficiency of all the cells is greatly improved.

In practice, however, it is almost impossible to measure channel response information between a transmitter and a receiver belonging to different cells, and even if the measurement is possible, the channel efficiency is greatly reduced in order to feed it back to the transmitter. In addition, even if the transmitter knows all channel information, its complexity is very large because the transmission scheme of all cells in the system must be optimized at the same time.

The present invention has been proposed to solve the above-described problems, and in a multi-cell environment in which a transmission scheme is determined in consideration of both the performance of its own cell and an adjacent cell using only information that can be realistically taken in the multi-cell environment. An object of the present invention is to provide a multiple transmit / receive antenna apparatus and a method thereof.

Another object of the present invention is to provide a multi-transmit / receive antenna apparatus and method in a multi-cell environment to reduce the complexity by determining each transmission independently without co-operation between cells in determining the transmission scheme. In providing.

In order to achieve the above object, a multi-transmit / receive antenna apparatus in a multi-cell environment according to a preferred embodiment of the present invention may include estimation of channel response information in a signal from a first means having a plurality of antennas for each cell. A multiple transmit / receive antenna apparatus in a multicell environment having a second means having a plurality of antennas capable of estimating a correlation matrix of a noise and an interference signal, the apparatus comprising:

The second means, the instantaneous performance calculation unit of the own cell to calculate the instantaneous performance of its own cell according to the transmission scheme of each cell using the estimated channel response information and the estimated noise and interference signal correlation matrix ; An average performance calculation unit of a neighbor cell that calculates average performance of the neighbor cell using pre-stored information when a signal is transmitted in a transmission scheme of each cell under the determined transmission power; A transmission method determination unit adopting a transmission method in consideration of the calculated instantaneous performance of the own cell and the average performance of the neighbor cell; And a feedback information transmitter for feeding back information on the determined transmission scheme to the first means of the corresponding cell.

In addition, in the multiple transmit / receive antenna method in a multi-cell environment according to an embodiment of the present invention, the estimation of channel response information and the correlation matrix of noise and interference signals in the signal from the first means having a plurality of antennas for each cell A multiple transmit / receive antenna method of a multiple transmit / receive antenna device in a multi-cell environment having second means having a plurality of antennas,

In each of said second means,

A first step of calculating an instantaneous performance of its own cell for each cell transmission method using the estimated channel response information and a noise and interference signal correlation matrix; A second step of calculating an average performance of a neighbor cell according to a transmission scheme of each cell with respect to a transmission power by using previously stored information; A third step of selecting a transmission scheme in consideration of the calculated instantaneous performance of the cell and the average performance of the neighboring cell; And a fourth process of feeding back information on the selected transmission scheme to the first means of the corresponding cell.

Hereinafter, a multi-transmit / receive antenna apparatus and method thereof in a multi-cell environment according to an embodiment of the present invention will be described with reference to the accompanying drawings.

First, the following matters are basically set before explaining this invention.

1) At the receiver of each cell ( i- th cell), the sum of the average frequency efficiency (approximate value) of neighboring cells whose parameters are the transmit power of the cell and the transmit antenna subset is a look-up table. Or otherwise.

2) The receiver of each cell ( i- th cell) can estimate channel response information from the transmitter of its cell, and can also estimate the correlation matrix of noise and interference signals in the received signal. This can be easily accomplished by conventional techniques. The estimation methods described below are just one example, and various methods are possible in addition to the estimation methods described below.

Estimation of Channel Response Information

Paper <CL Miller, DP Taylor, PT Gough, "Estimation of co-channel signals with linear complexity," IEEE Trans. Commun., Vol. 49, no. 11, pp. 1997-2005, Nov. 2001.>.

Estimation of Correlation Matrix of Noise and Interference Signals

In a multi-cell environment, the receiver receives the signal transmitted by the transmitter of its own cell, the signal transmitted by the transmitter of another cell (hereinafter referred to as an interference signal), and the noise signal. At this time, if the transmitter of the cell transmits a predefined pilot signal, and the channel response information between the transmitter and the receiver of the cell is estimated as described above, the signal transmitted from the transmitter of the cell may restore and subtract it. Therefore, only portions of noise and interference signals in the received signal can be extracted. By correlating the extracted noise and the interference signal over a predetermined time, the correlation matrix of the noise and the interference signal can be estimated.

3) The receiver of each cell knows the transmit power transmitted by the transmitter of its cell. In this system, if the power control is not performed, the transmission power is a fixed value, so it can be known from the receiver.In order to cancel the channel attenuation when the power control is performed, it is assumed that the transmission power is transmitted to the inverse of the channel attenuation. Since the attenuation can be estimated from the channel response information, the transmit power is also known. The transmission power estimation method described below is one example, and can be estimated by various methods other than this, and the present invention is not limited to the following description.

Estimation of Transmission Power

a) If the power is not adjusted, the receiving unit knows it because the transmit power is fixed.

b) In the case of power regulation, the purpose and method thereof are various, but in the specification of the present invention, power regulation aimed at compensating for channel attenuation will be described as an example. In the present invention, the channel response is expressed as the product of the channel attenuation and Rayleigh fading. Among them, channel attenuation is long-term fading, and Rayleigh fading can be thought of as short-term fading. Thus, using the estimated channel response information, the Rayleigh fading changes, but the channel attenuation does not change, taking the average value of the squares of the absolute values of each element of the channel response information matrix, thereby reducing the An estimate can be obtained. In this way, in proportion to the inverse of the estimated value obtained at the receiver (proportional constant is a fixed value), the transmit power is determined and fed back to the transmitter, and then the signal is transmitted at the determined transmit power.

1 is a block diagram of a multiple transmit / receive antenna apparatus in a multi-cell environment according to an exemplary embodiment of the present invention, and includes a transmitter 200 and a receiver 100 including a plurality of cells and each antenna having a plurality of antennas. . Here, for better understanding, the transmitter 200 may be viewed as a base station or the receiver 100 may be viewed as a mobile station. Of course, it may be assumed that the receiver 100 is a base station and the transmitter 200 is a mobile station.

In the following description, it is assumed that the transmitter 200 is a base station and the receiver 100 is a mobile station.

The receiver 100 includes a high frequency processor 10 for receiving a high frequency signal transmitted from a plurality of transmit antennas of the transmitter 200 using a plurality of receive antennas and converting the signal into a baseband signal; A channel response information estimator 12 for estimating channel response information from the baseband signal output from the high frequency processor 10 using a pilot signal or the like; A noise and interference signal correlation matrix estimator 14 for estimating a correlation matrix of noise and interference signals remaining after subtracting a signal transmitted by the transmitter 200 of its cell from the baseband signal output from the high frequency processor 10. ); The transmission power is determined using the channel response information estimated by the channel response information estimator 12, but when power adjustment is not required, the transmission power is determined using only known transmission power and only when power adjustment is required. A transmission power determiner 16; A cell according to a transmission method of each cell using the channel response information estimated by the channel response information estimator 12 and the noise and interference signal correlation matrix estimated by the noise and interference signal correlation matrix estimator 14. An instantaneous performance calculation unit 18 of its own cell for calculating the instantaneous performance of the cell; When transmitting a signal by the transmission method of each cell under the transmission power determined by the transmission power determining unit 16, the average performance of the neighboring cell is calculated by using previously stored information (for example, information stored in a lookup table). An average performance calculator 20; A transmission scheme in consideration of the instantaneous performance value of the own cell calculated by the instantaneous performance calculation unit 18 of the own cell and the average performance value of the neighboring cell calculated by the average performance calculator 20 of the neighboring cell. A transmission method determination unit 22 for determining A feedback information transmitter 24 for wirelessly feeding back the information on the determined transmission scheme and the transmission power as feedback information to the transmitter 200 of the corresponding cell; And an information restoring unit 26 for restoring information from the baseband signal output from the high frequency processor 10 and restoring the information in consideration of the transmission method determined by the transmission method determination unit 22.

The transmitter 200 includes: a feedback information receiver 50 for receiving feedback information wirelessly transmitted by the feedback information transmitter 22 of the receiver 100 using a reception antenna; A demultiplexer 52 for dividing an information signal to be transmitted into a plurality of signal streams; A plurality of signal streams are input from the demultiplexer 52 and the weight matrix and the power allocation value of each transmit antenna are based on the feedback information (information indicating the transmission scheme and the transmission power) received by the feedback information receiver 50. A transmission scheme implementation section 54 that multiplies the signal stream; And a high frequency processor 56 for converting the baseband signal output from the transmission method implementing unit 54 into a high frequency signal and then wirelessly transmitting the high frequency signal using a plurality of transmission antennas.

When the transmission scheme implementation unit 54 implements a transmission scheme using a transmission antenna subset selection scheme, the transmission antenna weight matrix is a unit matrix, the power allocation value is 1 / K _i for the selected antenna, and for other antennas. 0, where K _i is the number of transmit antennas belonging to the selected subset.

In the embodiment of the present invention, the instantaneous performance calculation unit 18 of the own cell, the average performance calculation unit 20 and the transmission method determination unit 22 of the adjacent cell are installed in the reception unit (for example, the mobile station) 100. Although it was supposed to be one, it may be provided in the transmitter (for example, base station) 200.

Next, a multi-transmit and receive antenna method in a multi-cell environment according to an embodiment of the present invention will be described with reference to the flowchart of FIG. 2.

The high frequency processor 10 of each receiver 100 receives a high frequency signal wirelessly transmitted from each transmitter 200, converts the signal into a baseband signal, and outputs the signal. The output baseband signal is sent to the channel response information estimator 12, the noise and interference signal correlation matrix estimator 14, and the information reconstruction unit 26 of the receiver 100.

The channel response information estimator 12 estimates the channel response information from the input baseband signal using a pilot signal or the like, and the noise and interference signal correlation matrix estimator 14 uses the input baseband signal. After subtracting the signal transmitted by the transmitter 200 of the cell, the correlation matrix of the residual noise and the interference signal is estimated (S10).

The correlated matrix of the estimated channel response information, noise, and interference signal is transmitted to the instantaneous performance calculation unit 18 of its own cell, and the instantaneous performance calculation unit 18 of its own cell receives the input information, that is, the estimation matrix. The instantaneous performance of its own cell is calculated for the transmission scheme of each cell using the correlated matrix of the channel response information, noise, and interference signal (S12).

Meanwhile, the estimated channel response information is also transmitted to the transmission power determining unit 16. The transmission power determining unit 16 determines the transmission power using the input channel response information and then determines the value of the determined transmission power. The average performance calculation unit 20 of the neighboring cell is transmitted. Accordingly, the average performance calculator 20 of the neighbor cells calculates the average performance of the neighbor cells according to the transmission scheme of each cell with respect to the transmission power by using the information already stored (S14).

 The two values calculated by the instantaneous performance calculation unit 18 of the own cell and the average performance calculation unit 20 of the adjacent cell are transmitted to the transmission method determination unit 22, and the transmission method determination unit 22 The transmission method is determined in consideration of the two input values (S16). The transmission method determination operation is performed by the description based on the following equations.

The determined transmission scheme is transmitted to the feedback information transmitter 24, and the feedback information transmitter 24 transmits the transmission power transmitted from the transmission power determiner 16 and information on the determined transmission scheme to the transmitter 200 of its cell. (S18).

Accordingly, the transmitter 200 of each cell transmits the signal through the transmission method based on the feedback inputted information (step S20). That is, the feedback information receiving unit 50 of the transmitting unit 200 of each cell receives the feedback information wirelessly transmitted by the receiving unit 100 of each cell through the receiving antenna, and sends it to the transmitting method implementation unit 54. The transmission method implementation unit 54 receives a plurality of signal streams from the demultiplexer 52 and weights each transmission antenna based on the feedback information (information indicating the transmission method and the transmission power) from the feedback information receiver 50. A matrix and a power allocation value are multiplied by each signal stream and output. The high frequency processor 56 converts an output value (baseband signal) from the transmission method implementation unit 54 into a high frequency signal and then uses a plurality of transmit antennas. Wireless transmission of the high frequency signal (S20).

When neighboring cells select a transmission method through the operations of S10 to S16, the correlation matrix of noise and interference signals received by each cell changes accordingly. Therefore, each cell repeats the process corresponding to S10 to S20 described above. According to the experimental results, the repetition process may be omitted since the performance difference between the cells that have been subjected to the repetition process and the case where the neighboring cells are not performed is not large.

When described in more detail using the equation as follows.

In a multi-cell system having a transmitter 200 with N _t transmit antennas and a receiver 100 with N _r receive antennas, a signal received at the receiver of each cell is modeled as in Equation 1 below. can do.

[Equation 1]

와 각 원소의 표준편차가 1인 확률 변수 행렬 G _i,j, 의 곱으로 표현된다(

). 이 때, i번째 셀의 송/수신부(100, 200) 간의 주파수 효율(즉, 성능)은 하기의 수학식 2와 같이 구할 수 있다. 하기의 수학식 2는 자신 셀의 순시적 성능 계산부(18)에서 사용된다.Here, r _i is the transmit power, H _{i, i} is the i-th cell in the signal vector (N _r × 1), P _i is a transmission unit 200 of the i th cell received by the receiver 100 of the i th cell transmitter 200 and the i receiving section 100, channel response information matrix (N _r × N _t) between, x _i is the signal vector (N _t × 1) sent by the transmitter of the i-th cell, P _j of the second cell is is the transmit power at the transmitter of the j th cell, H _{i, j} is the channel response information matrix (N _r × N _t ) between the transmitter of the j th cell and the receiver 100 of the i th cell, and x _j is the j th cell Is a signal vector (N _t × 1) transmitted from the transmitter of N, where n _i is a noise signal vector (N _r × 1) whose standard deviation applied to the receiver 100 of the i th cell is σ, and J _i is the i th cell. It is a set of indexes of cells that give an interference signal. In this case, H _{i, j} is the channel attenuation between the transmitter of the j- th cell and the receiver 100 of the i- th cell.

And the product of the random variable matrix G _{i, j, with} a standard deviation of 1 for each element (

). In this case, the frequency efficiency (ie, performance) between the transmitter / receiver 100 and 200 of the i- th cell may be obtained as in Equation 2 below. Equation 2 below is used in the instantaneous performance calculation unit 18 of its own cell.

[Equation 2]

Where I is a unit matrix of N _r × N _r , R _i is the correlation matrix (= E { x _i x _i ^H }) of the signal vector transmitted from the transmitter 200 of the i- th cell, where W _i , Q _i , Q _i ^H , W _i ^H ( W _i is i- th) Q _i is a diagonal matrix having, as a diagonal component, the square root of the power allocation value of the i- th cell. Thus, i songsik way of the second cell, determining a (that is, transmission antenna weight matrix and power allocation) the same as that of determining the R _i, the frequency efficiency of the i-th cell in accordance with changing the R _i (i.e., performance) In addition, the frequency efficiency (ie, performance) of the adjacent j- th cell j ∈ J _i also changes. Therefore, by changing the transmission scheme of the i-th cell in order to increase the average spectral efficiency of all the cells in the frequency efficiency and the j-th cells, the sum of the frequency efficiency of the (j∈ J _i) of the i-th cell into the objective function, maximizing this We need to find a transmission method to This can be expressed as Equation 3 below.

[Equation 3]

Here, argmax a { f } means parameter a that maximizes the function f . Blum's study described above increases the frequency efficiency (performance) of the entire cell by maximizing the sum of the instantaneous frequency efficiency (performance) C _i and C _{j in} the above equation.

However, R _i and the adjacent j in order to know the instantaneous spectral efficiency (capacity) relation between C _j-th cell from the sending unit 200 of the i th cell, as shown in Equation (2) to the j-th cell reception channel response You need to know the information, which is almost impossible in a real environment. In the present invention, to the algorithm, even if you do not know the instantaneous spectral efficiency without using a value of C _j, the average spectral efficiency channel response information from a particular transmitter by using a value of C _j to the reception of other cell operations.

In other words, the channel response is continuously changed with time, and the instantaneous frequency efficiency ( C _j ) can be calculated by Equation 2 above as a function of the channel response at a specific time. In contrast, the average frequency efficiency (called E ( C _j )) is the average of C _{j according} to the probability distribution function of the channel response. Therefore, E ( C _j ) is not a function of the instantaneous channel response but a function of the statistical characteristics of the channel response and thus does not require the instantaneous channel response information. In general, these statistical characteristic values do not change rapidly with time, and can be estimated based on the channel model.

That is, in the present invention, each transmission unit determines its own transmission scheme is equivalent to obtaining R _i satisfying Equation 4 below. In other words, the transmission method determination unit 22 of the present invention determines the transmission method by obtaining R _i satisfying Equation 4 below.

[Equation 4]

Even in this case, since the frequency efficiency of the cell is instantaneous, the transmitter needs to know channel response information (or corresponding transmit antenna weight matrix and power allocation information) between the transmitter and receiver of the cell. can do. Since this requires very large feedback information, in order to avoid this, the present invention uses transmit antenna subset selection. In this case, the feedback can be greatly reduced by selecting an appropriate transmission antenna subset using the channel response information measured by the receiver and feeding back only the information indicating the subset to the transmitter. Here, selecting the appropriate subset of transmit antennas is a description of the existing technology, and how to select in detail is dependent on the requirements of the system (e.g., minimizing error rate, maximizing frequency efficiency, etc.). It may vary. The present invention takes a method of maximizing the sum of the instantaneous frequency efficiency of its cell and the average frequency efficiencies of neighboring cells, which means that the instantaneous frequency efficiency of its cell and the neighboring cells of all the possible transmit antenna subsets are maximized. Calculate the sum of average frequency efficiencies and select the subset with the highest value. This may be represented by Equation 4 and Equation 10 below.

When the transmission method is selected according to the transmission antenna subset selection method, R _i may be represented by a diagonal matrix, and each diagonal element is 1 / K _i when the corresponding transmission antenna belongs to a subset, and 0 when it does not belong to a subset. Where K _i is the number of transmit antennas belonging to the subset. For example, in the case of four transmitting antennas, R _i representing a subset including the first and third transmitting antennas may be expressed as follows.

[Equation 5]

In this case, using Equations 2 and 5, C _j is expressed as Equation 6 below. Equation 6 below is used in the average performance calculator 20 of adjacent cells.

[Equation 6]

[ H _{i, j} ] _sub in the above equation is a submatrix of H _{i, j} composed of a row of H _{i, j} corresponding to a transmit antenna belonging to the antenna subset selected at the transmitter of the j- th cell. To simplify the equation, assuming that the number of the selected transmit antennas of the remaining cells except for the i- th cell is large enough, Equation 6 may be approximated as Equation 7 below.

[Equation 7]

Was 2, 4, wherein the second of the four anti-3,4 in the second line of the above equation are, respectively, equal to the expression N _r × K _i the frequency efficiency of the multi-antenna system in a one-to-one link, as is typical in a wireless environment G _i Assuming that each element of _{, j,} is a random variable that is independent of each other and follows a complex standard distribution, we can obtain the mean value as follows: [H. Shin and J. Lee, "Capacity of Multiple-Input Fading Channels: Spatial Fading Correlation, Double Scattering, and Keyhole," IEEE Trans. Inform. Theory, vol. 49, no. 10, pp. 2636-2647, Oct. 2003. Reference]

[Equation 8]

는 송/수신부 간의 채널 감쇄와 인접 셀에서의 송신전력에 관한 함수이고, 이 중 채널 감쇄는 그 확률 분포 함수를 채널 모델을 통해 알 수 있다. 또한 인접 셀에서의 송신전력은 전력 조절을 하지 않을 경우 고정된 값이고, 전력 조절을 할 경우 채널 감쇄를 보상시키는 값으로 하여, 역시 그 확률 분포 함수를 알 수 있다. 따라서,

의 확률 분포 함수

역시 구할 수 있다.In the ceremony

Is a function of channel attenuation between the transmitter / receiver and transmit power in an adjacent cell. Among these, channel attenuation can be known through a channel model. In addition, the transmit power in the adjacent cell is a fixed value when the power is not adjusted, and the probability distribution function can be known as a value that compensates for the channel attenuation when the power is adjusted. therefore,

Probability distribution function

Also available.

에 대해 평균값을 취할 수 있다.Equation 8 is as follows.

We can take an average value for.

[Equation 9]

와

는 수학식 7의 정의에서 보듯이 채널 감쇄와 송신전력, 수신 안테나의 개수에 대한 함수로써 송신 방식과 무관한 항이므로 송신 방식을 결정하는데 있어서 이를 고려하지 않아도 된다. 이를 자세히 살펴보면 다음과 같다.Through this process, the equation (7)

Wow

As is a function of channel attenuation, transmit power, and the number of receive antennas, as shown in the definition of Equation 7, the term does not need to be considered in determining the transmission method. Looking at it in detail as follows.

1) N _r is the number of receiving antennas mounted on the receiving unit, and it is obvious that it does not change depending on the transmission method, so it can be regarded as a fixed value.

2) Channel attenuation is given according to the state of the radio channel and thus cannot be changed by the transmitter.

3) The transmission power can be adjusted by the transmitter, but in the present invention, the transmission power is set to a value proportional to a predetermined value (when power adjustment is not performed) or the inverse of channel attenuation (when power adjustment is performed). Determination of the transmission method may be said to be made under the predetermined transmission power after the transmission power is determined. Therefore, the transmission power does not change depending on the transmission method.

와

를 무시하게 되면, 결국 수학식 4로 최적의 전송 방식을 구하는 것은 하기의 수학식 10으로 전송 방식을 구하는 것과 근사적으로 동일하다. 하기의 수학식 10은 송신 방식 결정부(22)에서 사용된다.Of Equation 7

Wow

When ignoring, eventually, obtaining an optimal transmission scheme with Equation 4 is approximately the same as obtaining a transmission scheme with Equation 10 below. Equation 10 below is used in the transmission method determination unit 22.

[Equation 10]

항 즉, 자신의 셀의 송신전력과 송신 안테나 부분집합을 매개변수로 하는 인접 셀 들의 평균적인 효율(의 근사값)들의 합을 나타내는 항을 목적함수에 둠으로써 다른 셀의 주파수 효율을 고려하여 자신의 셀의 전송 방식을 결정한다. 또한, 그

항은 자신의 셀의 송신부로부터 다른 셀의 수신부까지의 채널 반응 정보와 무관하여, 이를 송/수신부에서 알지 못하는 경우에도 본 발명을 수행할 수 있다. 아울러, 다른 셀의 전송 방식(즉, R _l , l??i)과도 무관하여, 다른 셀과의 공조(cooperation)를 할 필요없이 각각의 셀에서 독립적으로 수행이 가능하다. 하기에 제시하는 표는 송수신 안테나의 수가 각각 4개일 경우, 룩업테이블로 작성한

의 일례이며, 그 값의 상태적인 비교를 위해

를 차감해 준 값을 제시하였다. 이 표의 값에서 셀 최외각에 송신부 또는 수신부에 해당하는 이동국이 위치하였을 때의 평균적 송신 전력을 1로 하였고, 채널 감쇄는 경로 감쇄와 로그-노멀 페이딩의 곱으로 표현되며, 이 때 경로 감쇄의 지수값은 3.7, 로그-노멀 페이딩의 로그 표준 편차는 8dB로 하여 계산된 것이다.The present invention, as can be seen in the above equation (10)

In other words, the term representing the sum of the average efficiency (approximate values) of neighboring cells using the transmit power of the cell and the transmit antenna subset of the cell as a parameter is set in the objective function to consider the frequency efficiency of the other cells. Determine the transmission method of the cell. Also, that

The term can be performed even when the transmitter / receiver is not aware of the channel response information from the transmitter of the cell to the receiver of the other cell. In addition, regardless of the transmission scheme of other cells (that is, R _l , l ?? i ), it is possible to perform independently in each cell without having to cooperate with other cells. The table shown below is created with a lookup table when the number of transmitting and receiving antennas is four.

For example, for the state comparison of the values

The value given by subtracting is given. In this table, the average transmit power when the mobile station corresponding to the transmitter or receiver is located at the outermost cell is 1, and channel attenuation is expressed as the product of path attenuation and log-normal fading. The value is calculated as 3.7, and the log standard deviation of log-normal fading is 8 dB.

Transmission power K _i = 1 K _i = 2 K _i = 3 K _i = 4 10 ^-1 0.0029 0.0012 0.0004 0 10 ⁰ 0.0485 0.0205 0.0074 0 10 ¹ 0.4551 0.2067 0.0767 0 10 ² 2.4556 1.1975 0.4532 0 10 ³ 8.3589 4.3785 1.7106 0 10 ⁴ 19.0181 10.7317 4.3936 0

As described in detail above, according to the present invention, the transmission method is determined in consideration of the performance of both its own cell and the adjacent cell using only information that can be realistically taken in a multi-cell environment, and each cell in determining the transmission method. The complexity is reduced by determining this independently without co-operation between the two.

On the other hand, the present invention is not limited only to the above-described embodiment, but can be modified and modified within the scope not departing from the gist of the present invention, the technical idea to which such modifications and variations are also applied to the claims Must see

Claims (11)

For each cell, multiple transmission / reception in a multi-cell environment having a second means with multiple antennas capable of estimating channel response information in the signal from the first means with multiple antennas and a correlation matrix of noise and interference signals As an antenna device, The second means, the instantaneous performance calculation unit of the own cell to calculate the instantaneous performance of its own cell according to the transmission scheme of each cell using the estimated channel response information and the estimated noise and interference signal correlation matrix ; An average performance calculation unit of a neighbor cell that calculates average performance of the neighbor cell using pre-stored information when a signal is transmitted in a transmission scheme of each cell under the determined transmission power; A transmission method determination unit adopting a transmission method in consideration of the calculated instantaneous performance of the own cell and the average performance of the neighbor cell; And a feedback information transmitter for feeding back the information about the determined transmission scheme to the first means of the corresponding cell. The method of claim 1, The instantaneous performance calculation unit of the own cell obtains the instantaneous frequency efficiency of its own cell, and the obtained instantaneous frequency efficiency as a value of the instantaneous performance of its own cell, multiple transmit and receive antenna apparatus in a multi-cell environment . The method of claim 2, The average performance calculation unit of the neighboring cell calculates the average frequency efficiency of the neighboring cell, and the multiple transmit and receive antenna apparatus in a multi-cell environment, characterized in that the obtained average frequency efficiency as a value of the average performance of the neighboring cell. The method of claim 3, wherein The transmission method determining unit adopts a transmission method for maximizing the sum of the instantaneous frequency efficiency of the cell and the average frequency efficiency of the adjacent cells. The method of claim 4, wherein The instantaneous frequency efficiency of the own cell is expressed by the following equation

(Where, P _i is the transmit power at a transmitter of the i-th cell, H _{i, i} is sent sudanwa i th cell reception channel response information matrix (N _r × N _t between the means of the i-th cell), R _i Is the autocorrelation matrix of the signal vector transmitted by the transmitting means of the i- th cell, P _j is the transmission power of the transmitting means of the j- th cell, H _{i, j} is between the transmitting means of the j- th cell and the receiving means of the i- th cell The channel response information matrix of (N _r × N _t ), where R _j is the autocorrelation matrix of the signal vector transmitted by the transmitting means of the j- th cell, J _i is the index of the cells giving the interference signal to the i- th cell Is the standard deviation of the noise signal.) Multiple transmit and receive antenna apparatus in a multi-cell environment, characterized in that calculated by. The method of claim 5, The average frequency efficiency of the adjacent cell is expressed by the following equation

Where E {x} is the average value of x. Multiple transmit and receive antenna apparatus in a multi-cell environment, characterized in that calculated by. The method of claim 3, wherein And the transmission method determination unit limits the transmission method to a transmission antenna weight matrix as a unit matrix and to allocate the transmission power equally to a plurality of selected antennas. The method of claim 7, wherein And the feedback information transmitter transmits information indicating the plurality of selected antennas. The method of claim 8, The average frequency efficiency of the adjacent cell is expressed by the following equation

Where g _{j, l} and g _{j, j} and g _{j, i} are channel attenuations from the transmitting means of the l- th, j- th, and i- th cells to the receiving means of the j-th cell, respectively, [ G _{j, i} ] _sub is N _r × K _i represents the Rayleigh fading of the reception unit to the j-th cell from the selected transmission antenna in the i-th cell Matrix.) A multiple transmit / receive antenna device in a multi-cell environment, characterized in that the value calculated by. The method of claim 8, The average frequency efficiency of the adjacent cell is expressed by the following equation

(here,

,

Is,

ego,

Is

Is a probability distribution function of.) A multiple transmit / receive antenna device in a multi-cell environment, characterized in that the value calculated by. For each cell, multiple transmission / reception in a multi-cell environment having a second means with multiple antennas capable of estimating channel response information in the signal from the first means with multiple antennas and a correlation matrix of noise and interference signals A multiplex transmission and reception antenna method of an antenna device, In each of said second means, A first step of calculating an instantaneous performance of its own cell for each cell transmission method using the estimated channel response information and a noise and interference signal correlation matrix; A second step of calculating an average performance of a neighbor cell according to a transmission scheme of each cell with respect to a transmission power by using previously stored information; A third step of selecting a transmission scheme in consideration of the calculated instantaneous performance of the cell and the average performance of the neighboring cell; And And a fourth process of feeding back information on the selected transmission scheme to the first means of the corresponding cell.

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