KR19990026450A - Structure and Signal Receiving Method of Multicarrier Code Division Multiple Access Receiver Using Antenna Array - Google Patents

Abstract

The present invention relates to a structure and a signal receiving method of a multi-carrier code division multiple access (MC-CDMA) receiver using an antenna array. The present invention relates to an antenna array which does not use a position configuration stage for identifying a position of a mobile within a unit cell. By applying the CDMA scheme to spatially processing the signal received by the antenna array, we estimate the array response vector for each received mobile station signal and use this vector to determine the weight for optimal beamforming. After this, the structure of the MC-CDMA receiver and the signal receiving method are presented, which can direct the desired user to the antenna beam and reduce the unwanted user to increase the system capacity.

Description

Structure and Signal Receiving Method of Multicarrier Code Division Multiple Access Receiver Using Antenna Array

The present invention relates to a structure of a receiver and a signal receiving method of a multi-carrier code division multiple access (hereinafter referred to as MC-CDMA) mobile communication system. The present invention relates to a structure of a MC-CDMA receiver and a signal receiving method for performing beamforming to reduce intersymbol interference and to improve system capacity.

In a typical cellular system, an antenna is installed and operated in a base station to prevent cell interference by dividing the cell space into 120 degrees according to a service range. However, this method is still in its infancy, and recently, intelligent antennas have been installed in direct sequence code division multiple access (DS-CDMA) systems to provide spatial diversity and efficiently use available spectrum. A way of doing this is presented. Such an intelligent antenna is generally composed of a position estimating stage and an adaptive beam forming stage. The position estimating stage identifies the position of the moving object within the unit cell, and the adaptive beam forming stage forms an appropriate beam to maximize the signal-to-noise ratio and the signal-to-interference ratio in consideration of the distribution of the moving object estimated by the position estimating stage. It plays a role.

However, the DS-CDMA scheme has a disadvantage in that interference between chips increases when data is transmitted at high speed, which increases the complexity of hardware and limits the capacity of a user that can be accommodated by multi-user interference.

Accordingly, the present invention can compensate for distortion caused by frequency selective fading of a channel by applying an antenna array without a separate position estimator to the MC-CDMA scheme, thereby reducing inter-symbol interference (hereinafter referred to as ISI). It is an object of the present invention to provide a structure and a signal receiving method of an MC-CDMA receiver which can reduce and improve system capacity.

The structure of the MC-CDMA receiver according to the present invention for achieving the above object is to demodulate the signal received at the antenna array using an antenna array, a subcarrier and a Walsh code to perform beamforming without configuring a position estimating stage. A plurality of multicarrier code division multiple access receivers, an array response vector for estimating an array response vector of a signal transmitted to the antenna array, and obtaining a beamformable coefficient using a signal having the estimated array response vector and a demodulated signal And a plurality of optimal beamformers for performing optimal beamforming based on coefficients obtained by estimating the vector and the beamforming controller, the array response vector, and the response vector obtained by the beamforming controller.

In addition, the signal receiving method of the MC-CDMA receiver according to the present invention for achieving the above object comprises demodulating the divided signal received through the antenna array using a plurality of demodulator and the corresponding user Walsh code, respectively, Estimating a response vector of a corresponding user using each array covariance of the divided signals received through the array and each array covariance of the demodulated signal, and obtaining a coefficient of a beam former using the estimated array response vector. And outputting and combining the signals of the corresponding users excluding the interference signals of other users by using the coefficients of the beam former.

1 is a block diagram of an MC-CDMA receiver in accordance with the present invention.

FIG. 2 is a functional block diagram illustrating an m th module of the MC-CDMA receiver of FIG. 1. FIG.

* Explanation of symbols for main parts of the drawings

11 antenna array 12 MC-CDMA receiver block

13: array response vector and beamforming controller

14: Optimal Beamformer Block

In the present invention, a reception method using an antenna array that does not use a separate position estimation stage in the MC-CDMA scheme is presented. The MC-CDMA scheme combines multi-carrier modulation of Orthogonal Frequency Division Modulation (OFDM) and DS-CDMA scheme, with N narrowbands consisting of symbols larger than the delay dispersion of the channel. (narrow band) It is possible to reduce ISI by transmitting a subcarrier signal and to compensate for distortion caused by frequency selective fading of a channel using a single tap equalizer. By installing an antenna array in the MC-CDMA receiver structure and processing the received signal in the antenna array in the spatial domain, the array response vector for each received mobile station signal is estimated and the optimal beamforming is obtained using the vector. Find the possible weight. This factor can then be directed to the antenna beam and reduce the unwanted user's signal to improve system capacity.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

1 is a block diagram of an MC-CDMA receiver in accordance with the present invention, with an antenna array 11, an MC-CDMA receiver block 12, an array response vector and beamforming controller 13, and an optimal beamformer block 14. It is composed.

The MC-CDMA receiver block 12 is composed of N subcarriers and Walsh Hadarmard codes for demodulating the signal received from the antenna array 11. The array response vector and the beamforming controller 13 estimate the array response vector of the signal arriving at the antenna array 11 and obtain the beamforming coefficients using the signal having the estimated array response vector and the demodulated signal. . The optimal beamformer block 14 performs optimal beamforming based on the array response vector and the coefficient values obtained by the beamforming controller 13.

FIG. 2 is a functional block diagram illustrating an m th module of the MC-CDMA receiver of FIG. 1 and illustrates a case where one user signal is received through an antenna array.

The signals received through the S antenna arrays from the user are divided into S signals (X ₀ (t) to X _S-1 (t)) so that they can be demodulated using a plurality of carriers. The received signals X ₀ (t) to X _S-1 (t) each have N subcarriers (cos (w ₀ t + θ _{m, 0} ) to cos (w _N-1 t + θ _{m, N−).} Demodulated in the MC-CDMA receiver by a demodulator composed of ₁ ) and Walsh Hadamard codes (c _m [0] through c _m [N-1]) corresponding to the m th user code, wherein the array response vector and beamforming The controller uses the array covariance (Z ₀ to Z _S-1 ) of the signals received at the S antenna arrays and the array covariance of the signal demodulated by the m th user code to obtain the array response vector of the m th user. The estimated vector is then used to determine the coefficients of the beamformers (W ^* _{m, 0} to W ^* _{m, S-1} ) to form a beam suitable for maximizing the signal-to-noise ratio and signal-to-interference ratio of the m-th user. is obtained. the coefficients of the beamformer (W ^* _{m, 0} to W ^* _{m, S-1)} interference signal from the other user signals of that user is ruled out by the It can be and outputs a combination of the m-th output terminal after the interference signal is decreased in the m-th user signals from different users on.

As described above, according to the present invention, by applying the antenna array to the MC-CDMA receiver structure suitable for high-speed data transmission, the ISI can be reduced and the system capacity can be improved by compensating for distortion caused by the frequency selective fading of the channel. Excellent effect

Claims (2)

An antenna array for performing beamforming without configuring a position estimator; A plurality of multicarrier code division multiple access receivers that demodulate signals received at the antenna array using subcarriers and Walsh codes; An array response vector and a beamforming controller for estimating an array response vector of the signal transmitted to the antenna array and obtaining a beamforming coefficient using a signal having the estimated array response vector and a demodulated signal; And a plurality of optimal beamformers for performing optimal beamforming based on coefficients obtained by estimating the response vector obtained by the array response vector and the beamforming controller. Demodulating the divided signals received through the antenna array using a plurality of demodulators and corresponding user Walsh codes; Estimating a response vector of the corresponding user using each array covariance of the divided signals received through the antenna array and each array covariance of the demodulated signal; Obtaining coefficients of a beam former using the estimated array response vector; And outputting and combining the signals of the corresponding users, excluding the interference signals of other users, by using the coefficients of the beam former.