KR100625451B1 - Interference cancellation method in composite structure of smart antenna and interference cancellator - Google Patents

Abstract

The present invention relates to a method for removing interference signals in a combination device of a smart antenna and an interference canceller that performs partial interference signal removal by introducing an interference cancellation weight indicating reliability of a signal estimated as interference. A first step of despreading the received signal, determining a symbol, and calculating a first weight for any natural number k-1 interference signal using the information from the symbol determination process; Performing a weighted inverse operation on each of the k-1 interference signals to remove the first weight, and then respreading the k-1 interference signals; A third step of calculating k-1 second weights representing reliability of the input symbol by using the least square error value of the symbol calculated in the symbol determination process of the first step; And a fourth step of performing partial cancellation by multiplying the calculated second weight value for each of the k-1 respread interference signals.

Interference Cancellation Weight, Smart Antenna, Interference Canceller, Combiner

Description

Interference cancellation method in composite structure of smart antenna and interference cancellator             

1 is a configuration example of a coupling device of the smart antenna and the interference canceller to which the present invention is applied.

2 is a flowchart illustrating a method for canceling an interference signal in a combination device of a smart antenna and an interference canceller according to the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for removing interference signals in a combination device of a smart antenna and an interference canceller and a computer readable recording medium recording a program for realizing the method. Particularly, the present invention relates to a wideband code division multiple access (CDMA) code. Division Multiple Access) An interference signal removal method and a program for realizing the method, which allow the interference signal to be partially removed according to the estimated symbol reliability in the combination device of the smart antenna and the interference canceller to increase the capacity of the system. The present invention relates to a computer-readable recording medium having recorded thereon.

The characteristic of CDMA system is that unlike other wireless systems, signals of other users act as interference, and the capacity of the system is determined by the interference. Therefore, if the user's signal can be completely removed from the received signal, the capacity can be significantly increased.

As a method of inducing capacity increase by eliminating interference of other users, smart antennas and interference cancellers are widely studied. A combination of the two is also discussed. By combining the two, more effective dose escalation can be achieved.

The general combination of smart antenna and interference canceller is a form in which the output of the smart antenna is connected to the input of the interference canceller, and in some cases, the output information of the interference canceller is fed back into the input information of the smart antenna.

The combination of the smart antenna and the interference canceller induces a larger capacity increase by complementing the disadvantages of the two devices through the combination of the smart antenna and the interference canceller.

However, in the interference elimination process of the conventional interference eliminator, there is a problem that can cause serious signal distortion when the estimation is wrong by estimating and removing all signals except for itself as interference signals.

The present invention has been made in order to solve the above problems, and in the combined device of the smart antenna and the interference canceller to perform the partial interference signal cancellation by introducing an interference cancellation weight indicating the reliability of the signal estimated to be interference. It is an object of the present invention to provide a method of canceling an interference signal and a computer readable recording medium having recorded thereon a program for realizing the method.

In the present invention for achieving the above object, in the interference signal removal method applied to the combination device of the smart antenna and the interference canceller, after despreading the signal received through the smart antenna, the symbol is determined, the symbol determination A first step of calculating a first weight for an arbitrary natural number k-1 interference signal using information obtained in the process; Performing a weighted inverse operation on each of the k-1 interference signals to remove the first weight, and then respreading the k-1 interference signals; A third step of calculating k-1 second weights representing reliability of the input symbol by using the least square error value of the symbol calculated in the symbol determination process of the first step; And a fourth step of performing partial cancellation by multiplying the calculated second weight value for each of the k-1 respread interference signals.

In addition, the present invention, the processor, after despreading the signal received through the smart antenna, the symbol is determined, and using the information from the symbol determination process, the first weight for any natural number k-1 interference signal Calculating a first step; Performing a weighted inverse operation on each of the k-1 interference signals to remove the first weight, and then respreading the k-1 interference signals; A third step of calculating k-1 second weights representing reliability of the input symbol by using the least square error value of the symbol calculated in the symbol determination process of the first step; And a computer-readable recording medium having recorded thereon a program for realizing a fourth step of performing partial erasure by multiplying the calculated second weight value for each of the k-1 respread interference signals.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exemplary configuration diagram of a combination device of a smart antenna and an interference canceller to which the present invention is applied.

The combination of the smart antenna and the interference canceller described in the embodiment of the present invention is a form in which the adaptive smart antenna 1 is placed in front and the parallel interference canceller 2 is placed in the rear. This type is an optimal type that can improve the performance of the interference canceller by eliminating the interference signal that the smart antenna failed to remove and using the smart antenna output result for multi-user signal estimation.

1 illustrates a structure in which a smart antenna and an interference canceller are applied to the present invention.

The front part of FIG. 1 is an adaptive smart antenna part 1, which is composed of a plurality of antennas 11, a despread module 12, a weight calculator 13, and a symbol determination module 14. As shown in FIG. The weight vector used in the weight calculator 13 is adapted to gradually optimize the weight vector by applying a least mean square (LMS) algorithm using information from the symbol determination module 14.

The interference canceller 2 passes through the weight inverse operator 21 and the respread module 22, which are modules after the symbol determination module 14 of the smart antenna, and then removes the interference cancellation calculation module for calculating the interference cancellation weight p. 23). The signal output from the adaptive smart antenna via the symbol determination module is removed by the weight imposed on the smart antenna to recover to the spatially filtered signal, and re-spread using a pseudo noise (PN) code. The respread signal is then subjected to interference cancellation in parallel by the interference cancellation weight p.

In general, the interference canceller includes a serial interference canceller and a parallel interference canceller. In this embodiment, the interference canceller is described through a parallel interference canceller.

In general, the interference canceller has a problem of causing serious performance degradation when the estimation is wrong by removing all estimated other user signals. In the present invention, the interference elimination weight (p) is used to determine a part that is incorrectly estimated using the interference cancellation weight (p). Performance reduction was prevented by only performing the erase.

)을 도입하여 다음의 [수학식 1]와 같이 나타내었다.Since the interference cancellation weight (p) is closely related to the reliability of the input symbol, the minimum square error (MSE) value of the symbol calculated by the symbol determination module of the adaptive smart antenna (

) Was introduced as shown in Equation 1 below.

The interference canceller portion for performing interference cancellation by giving an interference cancellation weight in a combination device of a smart antenna and an interference canceller will be described in detail as follows.

In the interference canceller, a parallel interference canceller for partial interference cancellation is used. In general, in broadband CDMA, fast power control is performed so that there is almost no difference in the received signal strength between users. When the received signal strength is almost the same, the parallel interference canceller performs better than the continuous interference canceller.

In the present invention, by providing a partial interference cancellation method that gives reliability to the estimated signals, and determines whether to remove the interference according to the reliability, it was intended to reduce the error of the interference cancellation by the incorrect decision.

The signal output through the symbol determination module in the adaptive smart antenna is processed as follows. In order to restore the spatially filtered result, the weight imposed on the smart antenna is recovered and respread with a pseudo noise (PN) code. The respread signal for K users then performs partial interference cancellation in parallel.

As mentioned above, in the general interference elimination process, all of the K-1 symbols except itself are assumed to have the same reliability. In practice, however, the K-1 signals experience fading independent of each other, so that the K-1 estimation results do not have the same reliability. When the interference is removed based on a false estimation, the performance of the interference canceller decreases drastically. Therefore, the interference can be degraded by treating the low reliability signal and the high reliability signal in the same manner.

To compensate for this, the present invention introduces a reliability p for K-1 signals. Reliability (p) is a value between 0 and 1, and represents an interference cancellation weight that enables partial interference cancellation according to the estimated symbol reliability (p). Since this weight is directly related to the reliability of the symbol, it can be a specific function value using the minimum squared error (MSE) calculated at the time of beam formation.

Since the MSE is a value that gives the reliability of the symbol, if the MSE is large, it means that the difference from the reference signal is large. Using the interference cancellation weight function expressed by the exponential function, the interference cancellation weight of the i-th user in the k-th interference cancellation stage is expressed by Equation 1 above.

2 is a flowchart illustrating a method for canceling an interference signal in a combination device of a smart antenna and an interference canceller according to the present invention.

As described above, by applying the interference cancellation weight (p) by using the least square error (MSE) value of the symbol obtained from the adaptive smart antenna, it is possible to prevent the interference canceller from removing an incorrectly estimated signal component. This will be described according to the flow shown in the drawings.

First, a combination device of the smart antenna and the interference canceller is driven 201. Obtain a minimum squared error (MSE) value of the symbol in the smart antenna (202). This refers to an error value obtained by a minimum squared error (MSE) calculation method.

The least squares error (MSE) value of the symbol thus obtained is calculated by an exponential function to obtain an interference cancellation weight value (203). In this case, the calculation by the exponential function means that the interference cancellation weight value is obtained as shown in Equation 1 above. The larger the minimum squared error (MSE) value of the symbol, the closer the interference cancellation weight value is to zero. If the minimum squared error (MSE) value of the symbol is zero, the interference cancellation weight value is one.

The obtained interference elimination weight value is applied to a signal estimated as an interference signal to partially cancel the interference signal (204).

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

As described above, the present invention provides the overall performance by enabling partial interference cancellation for a signal estimation that is less reliable by introducing an interference cancellation weight value in a combination device of a smart antenna and an interference canceller that increases the capacity of a broadband CDMA system. It is effective to induce improvement.

Claims (4)

In the interference signal removal method applied to the combination of the smart antenna and the interference canceller, A first step of despreading a signal received through the smart antenna, determining a symbol, and calculating a first weight for an arbitrary natural number k-1 interference signal using information obtained from the symbol determination process; Performing a weighted inverse operation on each of the k-1 interference signals to remove the first weight, and then respreading the k-1 interference signals; A third step of calculating k-1 second weights representing reliability of the input symbol by using the least square error value of the symbol calculated in the symbol determination process of the first step; And A fourth step of performing partial cancellation by multiplying the calculated second weight value for each of the k-1 respread interference signals Interference signal removal method comprising a. delete The method of claim 1, The second weight is, And a value between 0 and 1 obtained using an exponential function with the least square error value of the symbol. On the processor, Despreading a signal received through a smart antenna, and then determining a symbol and calculating a first weight for an arbitrary natural number k-1 interference signal using information obtained from the symbol determination process; Performing a weighted inverse operation on each of the k-1 interference signals to remove the first weight, and then respreading the k-1 interference signals; A third step of calculating k-1 second weights representing reliability of the input symbol by using the least square error value of the symbol calculated in the symbol determination process of the first step; And A fourth step of performing partial cancellation by multiplying the calculated second weight value for each of the k-1 respread interference signals A computer-readable recording medium having recorded thereon a program for realizing this.

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