The present invention relates generally to spread spectrum receivers, and in particular to methods of optimizing the equalization in a communication receiver, with transmit and receive diversity, of a spread spectrum signal transmitted through multiple resolvable fading paths channel. The invention is suitable for use in applications involving W-CDMA transmission techniques, and it will be convenient to describe the invention in relation to that exemplary application.
In W-CDMA communication systems, multicode signals at the transmitter are orthogonal to each other. However, this orthogonality is lost as the signals propagate through a multi-path fading channel. A chip equalizer is employed in the W-CDMA receiver as a means to restore the orthogonality of the signal, and thereby improve the receiver performance.
Typically, implementations of chip equalizers include a finite impulse response (FIR) filter. The chip equalizer tries to compensate for multi-path interference by inverting the channel. A known method for computing optimal chip equalizer filter coefficients uses a direct inversion matrix method involving estimation of the channel gain matrix G from the expression G=HHH+βI, where HHH is the channel correlation matrix, I is identity matrix, and β is a scalar noise factor in a W-CDMA system. Chip level equalization based on the matrix inversion method requires extensive computation that involves matrix decomposition as well as backward and forward substitution.
In current 3rd generation partnership project (3GPP) standards, receive diversity is used to improve receiver downlink performance. Receive diversity uses multiple antennas at the receiver to enable stronger signal reception This translates to higher data rates and increases system capacity. Current 3GPP standards specify requirements for receivers based on a least minimum mean-square error (LMMSE) chip level equalizer (CLFE). Whilst implementation of the CLE is straightforward in the case of a communication system without transmit or receive diversity, implementation of the CLE in a communication receiver with transmit and receive diversity has yet to be implemented in a practical, computationally efficient manner.
There currently exists a need to provide a method of performing data equalization in a communication receiver with transmit and receive diversity that ameliorates or overcomes one or more disadvantages of the prior art. There also exists a need to provide a method of performing data equalization in a communication receiver with transmit and receive diversity that optimizes the performance of a chip level equalizer in the communication receiver. There further exists a need to provide a method for performing data equalization in a communication receiver with transmit and receive diversity that is simple, practical and computationally efficient to implement.
With this in mind, one aspect of the invention provides a method for performing data equalization in a communication receiver, the communication receiver forming part of a communication system with transmit and receive diversity, the method including the steps of:
Preferably, step (c) includes:
Preferably, the channel gain matrix Gi to be inverted is calculated from the expression
where I is the identity matrix.
Another aspect of the invention provides a chip equalizer for use in a communication receiver forming part of a communication system with transmit and receive diversity, the chip equalizer including one or more computational blocks for carrying out the above described method.
The following description refers in more detail to various features of the invention. To facilitate an understanding of the invention, reference is made in the description to the accompanying drawings where the method for performing data equalization and the chip equalizer are illustrated in preferred embodiments. It is to be understood that the invention is not limited to the preferred embodiments as shown in the drawings.
In the drawings:
Referring now to
There currently exists two different types of transmit diversity modes, namely Space Time Transmit Diversity (STTD) and Closed Loop Transmit Diversity Mode (CLM). Accordingly, space-time encoding or a CLM weighting is applied by a symbol processing block 22 to the symbols to be transmitted to the receiver 12. Space-time encoded symbols or CLM weighted symbols are provided to symbol spreaders 24 and 26.
Following spreading, the data symbols are effectively transferred to the communication receiver 12 over different propagation paths by the use of multiple reception antennas at the communication receiver 12, as well as multiple transmission antennas. In this example, two exemplary receiving antennas 28 and 30 are illustrated and two transmission antennas have been used to transmit the data symbols, but in other embodiments of the invention any number of receiving and/or transmission antennas may be used.
During transmission of the data symbols to the communication receiver 12, noise characterized by variance σ2 is effectively introduced into the dispersive channels 14 to 20. The communications receiver 12 includes an equalizer 32 designed to restore the transmitted data signals distorted by the dispersive channels 14 to 20 and the noise introduced into those dispersive channels.
Selected computational blocks of the equalizer 32 are illustrated in
Channel estimates for the dispersive channel received at each i-th reception antenna are computed within the receiver 12 and provided as an input to the channel matrix calculation block 34. The channel estimates hli, where l=0, 1, 2, . . . , L−1 are received by the channel matrix calculation block 34 for the L multiple resolvable fading paths of each transmission channel received by each i-th reception antenna.
The channel response matrix Ĥi,j for each i-th receiver antenna and each j-th transmitter antenna is constructed from, the received channel estimates by consecutively shifting a channel vector column, by column, where the channel vector is formed by arranging the L channel estimates hli,j in their multi-path position in the direction of the column. In the example shown in
A channel gain matrix Gi is then constructed for each i-th receiver based upon the estimate of the channel response matrices Hi,1 and Hi,2 together with an estimate of the scale and noise factor in the communication system 10. The channel gain matrix Gi is calculated according to the following equation:
G=Ĥ1,1HĤ1,1+Ĥ1,2HĤ1,2+Ĥ2,1HĤ2,1+Ĥ2,2HĤ2,2+{tilde over (β)}I
or Gi=Ĥi,1HĤi,1+Ĥi,2HĤi,2+{tilde over (β)}iI
where Ĥi,1 and Ĥi,2 are the channel response matrices for the two dispersive channels received at each i-th receiver antenna, Ĥi,1H and Ĥi,1H are respectively the hermitian transpose of those channel response matrices, {circumflex over (β)} is an estimate of the noise factor of the communication system 10 and I is the identity matrix. Ĥi,jHĤi,j is the channel correlation matrix for each i-th dispersive channel in the communication system 10. The estimate {circumflex over (β)} of the noise factor in the communication system 10 can be computed by the receiver 12 in the manner described in United States Patent Application 2006/0018367, filed 19 Jul. 2005 in the name of NEC Corporation, the entire contents of which are incorporated herein by reference.
The channel gain matrix Gi must then be inverted in the matrix inversion block 38. A computationally efficient series of steps performed by the matrix inversion block 38 are illustrated in the flow chart shown in
At step 72, a forward substitution is then performed to solve the equation
to obtain a column vector d. The lower triangular matrix L, the column vector d and the resultant column vector e are schematically represented in
At step 74, a backward substitution is then carried out to solve the equation
{circumflex over (L)}Hĉ0={circumflex over (d)}
where
{circumflex over (L)}H[i,j]=LH[i+(N−1)/2, j+(N−1)/2]
∀0≦i,j≦(N−1)/2
to obtain half of vector c0 (denoted as ĉ0) corresponding to the middle row of the matrix Gi−1.
co[(N−1)/2+k]=ĉ0[k], c0[k]=c0[N−1−k]*, k=0, . . . , (N−1)/2
At step 76, the vectors wi of filter coefficients for each of the FIR filters 40 to 46 can be obtained by computing wi=c0HHiH for each i-th filter.
The input data ri is periodically updated with filter coefficient vectors wi during operation of the receiver 12. Despreader blocks 48 to 54 perform despreading operations on the input data symbol estimates from the multiple resolvable fading paths received respectively by the reception antennas 28 and 30. Accordingly, each despreader block obtains estimated symbols corresponding to each i-th receiver antenna and j-th transmitter antenna combination.
The STDD or CLM processors 56 and 68 then respectively act to decode the symbol estimates derived from input date received at the receiver antennas 28 and 30.
The combining block 60 acts to combine the decoded symbol estimates to obtain equalized data symbols.
Since the linear equations solved in the forward substitution step 72 and backward substitution step 74 has N and (N+1)/2 unknowns, solving them only requires calculation complexity of 0(N2). This significantly reduced computational complexity and enables the use of the equalizer 32 in practical communication.
It will be appreciated from the foregoing that in a communication system, calculating the filter coefficients for an equalizer at the receiver using direct matrix inversion would normally require up to O(N3) complex multiplications for forward and backward substitutions processing, where N is dimension of the square channel matrix to be inverted. This high level of computational complexity is a prohibitive factor for this method to be used in practical communication device. The above-described equalizer uses an efficient method of calculation requiring only 0(N2) complex multiplications for forward and backward substitutions processing to obtain exactly the same performance as normal equalizer employing direct matrix inversion. The simplified calculation is achievable by exploiting the special property (Hermitian and Positive Definite) of the channel response matrix G as well as the way filter coefficients are calculated in a particular realization of the equalizer receiver.
Finally, it should be appreciated that modifications and/or additions may be made to the equalizer and method of calculating filter coefficients for an equalizer without departing from the spirit or ambit of the present invention described herein.
This application is based upon and claims the benefit of priority from Australian patent application No. 2006907315, filed on Dec. 28, 2006, the disclosure of which is incorporated herein in its entirety by reference.
Number | Date | Country | Kind |
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2006907315 | Dec 2006 | AU | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2007/074360 | 12/12/2007 | WO | 00 | 6/24/2009 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/081715 | 7/10/2008 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
7492815 | Guo et al. | Feb 2009 | B2 |
8036295 | Yoshida | Oct 2011 | B2 |
20060018367 | Bui | Jan 2006 | A1 |
20060291581 | Onggosanusi et al. | Dec 2006 | A1 |
20100111157 | Sawai | May 2010 | A1 |
Number | Date | Country |
---|---|---|
9741647 | Nov 1997 | WO |
02060082 | Aug 2002 | WO |
03047032 | Jun 2003 | WO |
2006016722 | Feb 2006 | WO |
Number | Date | Country | |
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20090323774 A1 | Dec 2009 | US |