KR100749742B1 - Weight vector estimate apparatus and method for rake receiver - Google Patents

Abstract

The present invention relates to an apparatus and method for estimating a weight of a rake receiver that can increase the capacity of a base station in a next generation mobile communication system (WCDMA) using an up-link beamforming technique by a smart antenna. A channel estimator for estimating channel information from a despread signal of a control channel (DPCCH) signal separated from a signal received from an antenna; A first multiplier for compensating a despread signal of the control channel (DPCCH) with channel information detected by the channel estimator; A second multiplier for estimating channel information from the beamformed signal of the despread control channel (DPCCH) signal and compensating for the control channel (DPCCH) signal; This can be achieved by including an adaptive weight estimator that receives a compensated control channel (DPCCH) signal through the first and second multipliers and obtains a weight.

Description

WEIGHT VECTOR ESTIMATE APPARATUS AND METHOD FOR RAKE RECEIVER}

1 is an exemplary view for explaining a general beamforming

Figure 2 is a block diagram showing the configuration of a rake receiver of a conventional mobile communication system.

3 is an exemplary view showing a frame structure of a general uplink channel.

Figure 4 is a block diagram showing the configuration of a rake receiver of a mobile communication system according to the present invention.

*** Description of the symbols for the main parts of the drawings ***

10: first DPDCH reverse diffuser 11 DPCCH reverse diffuser

12: DPDCH beamformer 13, 19: first and second DPCCH beamformer

14: DPDCH data buffer 15: channel estimator

16: DPDCH combiner 17: frame buffer

18: second DPDCH reverse diffuser 20: DPCCH data buffer

21: first DPDCH coupler 22: second DPCCH coupler

23: adaptive weight estimator 100: channel estimator

MUL1 ~ MUL4: Multipliers

The present invention relates to a rake receiver of a mobile communication system. In particular, the capacity of a base station can be increased in a next generation mobile communication system (WCDMA) by using an uplink beamforming technique using a smart antenna. The present invention relates to an apparatus and method for estimating a weight of a rake receiver.

Recently, as the demand for mobile communication increases rapidly, much attention has been focused on researches for effectively using a limited spectrum.

Originally, mobile communication such as cellular and PCS is a communication method that effectively uses a limited spectrum, while dividing a cell more and more increases the efficiency of the spectrum, while incurring a lot of additional cost for installing a base station for dividing a cell and frequent handoff. There is a problem in that communication disruption or communication reliability inevitably exists.

Therefore, recently, new researches are being conducted to increase communication capacity and improve communication quality by applying advanced antenna technology without increasing base stations.

The advanced antenna technology uses a smart antenna technology, which concentrates radio waves in a direction of a desired subscriber and reduces and transmits interference signals of other subscribers, thereby dramatically improving performance of an existing mobile communication system. Says technology.

Advantages of the smart antenna are, first, the signal is not distributed and gathered to the desired place, the gain of the signal (Gain) is increased to increase the coverage (coverage) per base station, and also increases the gain As a result, the power consumption of the portable terminal can be reduced and the battery usage time is increased.

Second, by effectively eliminating unwanted interference signals, a large number of subscribers can be accommodated in the case of voice communication, and high-speed data communication is possible in the case of data communication.

Third, since the smart antenna also performs a spatial filter effect, it is possible to greatly reduce the interference effect due to multipath.

Smart antennas having the above characteristics can be classified into various types according to the standard. Among them, the smart antennas are classified by the most common beamforming method. It can be classified as (Adaptive beam smart antenna).

In the fixed beam method, the antenna beam pattern is fixed as shown in FIG. 1 (a). In the adaptive beam method, the antenna beam pattern may be changed according to time or the surrounding environment as shown in FIG.

FIG. 2 is a block diagram showing a configuration of a rake receiver of a conventional mobile communication system, wherein a first DPDCH despreader 10 that despreads a signal received from an antenna into a data channel (DPDCH) signal and a control channel (DPCCH) signal is despread. And a DPDCH beamformer 12 and a first and second DPCCH beamformers 13 and 19 for beamforming by multiplying the despread signal by a weight vector; A channel estimator for estimating channel information from the DPDCH data buffer 14 and the DPCCH data buffer 20 for buffering and outputting each of the beamformed channel (DPDCH, DPCCH) signals and the beamformed control channel (DPCCH) signal (15), a multiplier (MUL1, MUL2) for compensating beamformed data with the channel information detected by the channel estimator (15), and a combination of the fingers of the compensated channel (DPCCH) signal. A first DPDCH combiner 21 output to the type weight estimator 23, and the second And a second DPCCH combiner 22 which combines the fingers of the signal output from the DPCCH beamformer 19 to the adaptive weight estimator 23 and the channel estimator 15.

The frame buffer 17 and the second DPDCH despreader 18, which are not described in the above configuration, output the finger signal coupled by the DPDCH combiner 16 in one frame period to output the despread signal to a higher level. .

In addition, the adaptive weight estimator 23 obtains and outputs a weight vector from the despreaded control channel (DPCCH) signal and the signals output from the first and second DPCCH combiners 21 and 22, thereby outputting each channel beam. The formers 12, 13, and 19 allow beamforming by the weight vector.

Since the signal flow of the data channel DPDCH in the above embodiment does not have much relation with an algorithm for obtaining a weight vector, which is the subject of the present invention, a detailed description thereof will be omitted.

However, since the adaptive weight estimator 23 receives a control channel (DPCCH) signal as it is, there is a problem that a phase detection error (Phase Ambiguity) of 180 ° may occur.

Accordingly, the present invention has been made to solve the above problems, and when deriving a weight vector for beamforming from an adaptive weight estimator, the despreaded control channel signal and the beamformed control channel signal are channeled. It is an object of the present invention to provide an apparatus and method for estimating a weight of a rake receiver to prevent a phase detection error (Phase Ambiguity) from occurring by receiving a signal compensated by information and obtaining a weight.

The present invention for achieving the above object comprises: a channel estimator for estimating channel information from a despread signal of a control channel (DPCCH) signal separated from a signal received from an antenna; A first multiplier for compensating a despread signal of the control channel (DPCCH) with channel information detected by the channel estimator; A second multiplier for estimating channel information from the beamformed signal of the despread control channel (DPCCH) signal and compensating for the control channel (DPCCH) signal; And an adaptive weight estimator that receives the compensated control channel (DPCCH) signal through the first and second multipliers to obtain a weight.

The present invention for achieving the above object relates to the configuration of a rake receiver of a base station up-link modem to which a smart antenna technology can be applied, and for beamforming at a symbol level at which an antenna signal is despread When the weight vector is obtained, the weight vector is obtained using the channel-compensated signal of the despread control channel (DPCCH) signal.

In addition, the present invention for achieving the above object, according to the channel information estimated using the data after the beamforming (Despread) control channel (DPCCH) signal, the despreading control channel ( A weight vector is obtained using the channel compensated signal of the DPCCH signal.

For reference, the rake receiver refers to a receiver having a function of separating two signals having a time difference (delay) from each other, and the frame structure of an uplink (DPCH) channel structure is shown in FIG. As shown, a Dedicated Physical Data Channel (DPDCH) and a Dedicated Physical Control Channel (DPCCH) including control information for the data channel are configured in units of one slot.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail. First, in adding reference numerals to the components of each drawing, only the same components have the same reference numerals as much as possible even if they are displayed on different drawings.

In addition, many specific details, such as specific processing flows, in the following description are intended to provide a more general understanding of the invention, and it is understood that the invention may be practiced without these specific details. Will be self-evident.

4 is a block diagram showing a configuration of a rake receiver of a mobile communication system according to the present invention, in which a channel compensated signal of a despread control channel (DPCCH) signal and a channel compensated signal of a beamformed control channel (DPCCH) signal are shown. Is input to the adaptive weight estimator to output a weight vector.

That is, the first DPDCH despreader 10 and the DPCCH despreader 11 that despread and despread a signal received from the antenna into a data channel (DPDCH) signal and a control channel (DPCCH) signal are included in the despread signal. DPDCH beamformer 12 and first and second DPCCH beamformers 13 and 19 which multiply by weight vector and beamform the beamformed signals, and buffer and output each of the beamformed channel (DPDCH and DPCCH) signals. A DPDCH data buffer 14 and a DPCCH data buffer 20, a channel estimator 15 estimating channel information from the beamformed control channel (DPCCH) signal, and a channel detected through the channel estimator 15. A first DPDCH combiner 21 for combining the multipliers MUL1 and MUL2 for compensating the beamformed data with information and the fingers of the compensated channel DPCCH signal and outputting them to the adaptive weight estimator 23. And adaptive weights by combining the fingers of the signal output from the second DPCCH beamformer 19. In the rake receiver composed of the regular 23 and the second DPCCH combiner 22 output to the channel estimator 15, the channel estimator 100 for estimating channel information from the despread signal output from the DPCCH despreader 11 And a multiplier MUL3 for compensating the DPCCH inverse spread signal with the channel information detected through the channel estimator 100, and the DPCCH inverse spread signal with the channel information detected through the channel estimator 15. The apparatus further includes a multiplier MUL4, and the adaptive weight estimator 23 for outputting weights to the beamformers 12, 13, and 19 receives a signal compensated through the multipliers MUL3 and MUL4. And to obtain a weight.

The rake receiver of the present invention configured as described above despreads the data channel (DPDCH) signal and the control channel (DPCCH) signal for each antenna signal inputted through the multiple antennas, and then first of each antenna Channel estimation is performed using a despread control channel (DPCCH) signal, and weights for beamforming are calculated using data compensated for channels in each path.

Prior to the weight estimation by the adaptive weight estimator 23 as described above, by performing the compensation by estimating the channel information by the channel estimator 100, the 180 ° phase detection of the adaptive weight estimator 23 which has been a conventional problem It is possible to prevent the generation of phase ambiguity and to obtain better beamforming weights from the control channel (DPCCH) signal.

In other words, by compensating for the despread control channel (DPCCH) signal by the updated beamforming weight as described above, a control channel (DPCCH) signal with no interference is obtained, and again, the channel is estimated using a channel estimator. The estimated channel information is used to compensate for the despread and beamformed data channel (DPDCH) signal for each antenna signal.

As described above, the apparatus and method for weight estimation of the rake receiver of the present invention can reduce interference caused by other user signals by beamforming, thereby increasing capacity of the base station system, cell coverage area, and high-speed data service. It has the effect of making it work.

Claims (5)

A channel estimator for estimating channel information from a despread signal of a control channel (DPCCH) signal separated from a signal received from an antenna; A first multiplier for compensating a despread signal of the control channel (DPCCH) with channel information detected by the channel estimator; A second multiplier for estimating channel information from the beamformed signal of the despread control channel (DPCCH) signal and compensating for the control channel (DPCCH) signal; And an adaptive weight estimator configured to receive a compensated control channel (DPCCH) signal through the first and second multipliers to obtain a weight. 2. The weight estimation of the rake receiver of claim 1, wherein the weights output from the adaptive weight estimator are fed back to beamform newly despread data channel (DPDCH) signals and control channel (DPCCH) signals. Device. A first step of despreading a data channel (DPDCH) signal and a control channel (DPCCH) signal for each antenna signal inputted through the multiple antennas; Estimating channel information using despread control channel (DPCCH) signals of each antenna; And a third step of calculating a weight for beamforming by using the data compensated for the channel of each path by the channel information. 4. The channel compensation data of claim 3, wherein the channel compensation data for calculating the weights is data obtained by compensating for the control channel signal input by being despread by the channel information estimated from the despread signal of the control channel (DPCCH) signal. A weight estimation method of a rake receiver. 4. The channel compensation data of claim 3, wherein the channel compensation data for the weight calculation is compensated for the control channel signal that has been despread by the channel information estimated from the signal beamforming the despread signal of the control channel (DPCCH) signal. Weight estimation method of a rake receiver, characterized in that the data.

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