The present invention relates to the field of precoding transmission blocks in communication systems.
In telecommunications, transmissions are often performed by means of block transmission schemes. It is then common to use guard intervals (GI) to ensure that distinct blocks do not interfere with one another. The guard intervals are for example cyclic prefixes, zero-paddings, or pseudo-noise sequences.
The use of guard intervals combats intersymbol interference and intercarrier interference. In the guard interval, no or only redundant information is transmitted. This seriously limits the spectral efficiency of block transmission schemes. For example, a telecommunication system with a guard interval whose length is a quarter of the block length, 20% of the time (and thus of the achievable throughput) is wasted.
“Precoder for DMT with insufficient cyclic prefix” in Proc. IEEE International Conference on Communications, 1998, vol. 1, pp. 339-343 by Kok-Wui Cheong and J. M. Cioffi describes the introduction of a precoder at the transmitter intended to reduce distortions due to insufficient length of the cyclic prefix used in the guard interval. The precoder is arranged to reduce the distortion by processing the signals at the transmitter such that the signals appear to be undistorted at the receiver.
It is one object of the present invention to improve the precoder so as to be able to at least reduce the required Guard Interval.
This has in one example been achieved by means of a precoder for a communication system arranged to provide transmission blocks for transmission over a transmission channel based on inputted symbol blocks. The precoder is arranged to pre-distort each symbol block based on an estimate of the characteristics of the transmission channel so that the corresponding transmission block appears to be undistorted after transmission over the transmission channel. The precoder is arranged to provide said predistortion by applying Tomlinson-Harashima precoding on a sum of a first measure corresponding to predistortion so as to remove intrasymbol interference and a second measure corresponding to predistortion so as to remove intersymbol interference.
Because both predistortion so as to remove intrasymbol interference and predistortion so as to remove intersymbol interference is accomplished with the Tomlinson-Harashima-based precoding, the precoder allows for ISI/ICI-free block transmission. Thereby the need for a Guard Interval can even be eliminated entirely. The precoder allows for low-latency (short block length) high-data rate block transmission over media with severe dispersion. The precoding allows instantaneous symbol decisions of the receiver, which greatly simplifies the application of channel coding schemes.
In one example, each symbol block is within a predetermined range and the precoder is arranged to predistort each symbol block based on the Tomlinson-Harashima precoding so as to map the thus provided transmission block t(i) into the predetermined range.
The second measure is in one example based on an intersymbol interference measure (Pisi) for the transmission channel and a preceding transmission block.
The first measure is in one example based on an intrasymbol measure (Pici) and the inputted symbol block. The first measure is for example based on a matrix decomposed from the intrasymbol measure (Pici) and on the inputted symbol block.
In one example, the precoder is arranged to recursively calculate for each inputted symbol block (x(i)) an intermediate symbol block (ξ) as
ξ(k){circumflex over (=)}modM(R(k,k:N)ξ(k:N)+q(k))−R(k,k+1:N)ξ(k+1:N)−q(k),
wherein the intermediate symbol block (ξ) is initially assigned to the value of the inputted symbol block (x(i)) or the like. The precoder can then be arranged to determine each transmission block t(i) based on the intermediate symbol block (ξ) and based on a transposed modulation matrix.
The precoder comprises in one example a pre-processing unit arranged to determine the intersymbol interference measure (Pici) and the intrasymbol interference measure (Pici). The pre-processing unit is then arranged to decompose the intrasymbol interference measure (Pici) into a plurality of matrices (Q, R, D), wherein at lest one of the matrices is used in pre-distorting the symbol blocks.
One advantage of using at least one of said matrices in the precoder is that it does not require the calculation of an inverse matrix so as to provide the “predistortion” to the signals. The application of an inverse matrix may result in large transmit power; the power required depends on the channel realization at hand. The precoding matrices are herein instead provided using linear matrix operations.
One first matrix (R) is in one example an upper triangular matrix. The pre-processing unit can be arranged to decompose the intrasymbol interference measure (Pici) into a at least three matrices (Q, R, D), wherein one second matrix (Q) is unitary and one third matrix (D) is diagonal.
The present invention relates further to a transmitter part for a communication system comprising a precoder according to the above.
The present invention further relates to a communication system comprising a transmitter part according to the above. In one example, the communication system comprises further a receiver arranged to provide decoded symbol blocks based received transmission blocks transmitted over the transmission channel.
The receiver can be arranged to calculate each decoded symbol block as
{circumflex over (x)}(k){circumflex over (=)}modM(Py)(k)
wherein modM is the Tomlinson-Harashima precoding (modM) operator, and wherein P is based on an intrasymbol interference measure (Pici) for the transmission channel (120).
In a case wherein the communication system is a multicarrier system, the receiver P can be defined as P=D E W, wherein D is based on an intrasymbol interference measure (Pici) for the transmission channel (120), E is an equalizer and W is a modulation matrix such as the normalized DFT matrix. D is for example a diagonal matrix.
In a case, wherein the communication system is a single carrier communication system, P can defined as P=D WH E W, wherein D is based on an intrasymbol interference measure (Pici) for the transmission channel (120), E is an equalizer and W is a modulation matrix such as the normalized DFT matrix. D is for example a diagonal matrix.
The present invention also relates to a receiver for a communication system arranged to provide decoded symbol blocks based received transmission blocks (y(i)) transmitted over a transmission channel. The receiver is arranged to calculate each decoded symbol block as {circumflex over (x)}(k){circumflex over (=)}modM(Py)(k), wherein modM is the Tomlinson-Harashima precoding operator, and wherein P is based on an intrasymbol interference measure for the transmission channel.
The present invention also relates to method a method for providing transmission blocks for transmission over a transmission channel in a communication system. The method comprises steps of receiving inputted symbol blocks and pre-distorting the received symbol blocks. The received symbol blocks each are within a predetermined range. The pre-distortion is performed based on an estimate of the characteristics of the transmission channel so that the corresponding transmission block appears to be undistorted after transmission over the transmission channel. The predistortion comprises applying Tomlinson-Harashima precoding on a sum of a first measure corresponding to predistortion so as to remove intrasymbol interference and a second measure corresponding to predistortion so as to remove intersymbol interference.
In
The communication system 100 comprises a transmitter part 110, a transmission channel 120 and a receiver part 130. The transmitter part 110 is arranged to receive input signals. The communication system will in the following be described with reference to a multicarrier system. In a frequency domain equalized single carrier system, there is no such notation as time domain and frequency domain in the transmitter. In the multicarrier system, each input signal is a frequency domain representation of a symbol block X which is to be transmitted over the transmission channel 120. The length of each symbol block is N. The transmitter part 110 is arranged to process each symbol block so as to provide as an output a corresponding transmission block t to the transmission channel 120.
The transmitter part 110 comprises in the shown example a Hermitian operator unit 111 arranged to receive the input signal in the form of a symbol block X and provide an output signal x, which obeys Hermitian symmetry (and consequently ensures a real-valued transmit signal t). The Hermitian operator 111 is known in the art and will not be described in detail herein. In one example, wherein the communication system is a DMT system, the Hermitian operator unit is arranged to provide a real-valued baseband transmit signal. Alternatively, the Hermitian operator is omitted. In one example, the Hermitian operator unit 111 is omitted in a OFDM system. In the illustrated example, comprising the Hermitian operator unit 111, the output from the Hermitian operator unit 111 is fed to a precoder 112 of the transmitter part 110. In an alternative example, wherein the Hermitian operator unit 111 is omitted, the input signal is directly provided to the precoder 112.
The precoder 112 is arranged to provide time domain transmission blocks t for transmission over the transmission channel 120. The precoder will be described more in detail below. The precoder 112 is in the shown example arranged to output the time domain signal transmission blocks to a unit 114 arranged to add a prefix or the like to the transmission blocks so as to provide a Guard Interval (GI). In one alternative example, the unit 114 arranged to add a prefix is omitted. The transmission blocks t provided by the precoder 112 and possibly provided with an associated prefix are fed to a transmitter 115. In one example, the transmitter comprises a parallel-to-serial converter (not shown) arranged to output the data of the transmission blocks t (possibly provided with an associated prefix) as a serial stream to an antenna for further transmission over the transmission channel 120.
The transmission channel 120 comprises for example a dispersive media such as an air interface. The dispersive media causes inter-block-interference (herein referred to as inter-symbol-interference) and intra-block-interference. In multicarrier systems, the intra-block-interference is often referred to as inter-carrier-interference. For blocked single carrier systems, there is no such notation as ‘subcarriers’; the intra-block-interference may for example be referred to as linear distortion. Noise is added to the transmission blocks t over the transmission channel 120. The dispersive transmission channel 120 is modelled by a channel impulse response herein denoted h. The receiver part 130 will be described more in detail below.
In
The pre-processing unit 216 is arranged to calculate a first measure Pici of an inter-carrier interference associated to the transmission channel 120. The intercarrier interference measure Pici is computed as:
Pici{circumflex over (=)}TH−1{tilde over (H)}TH,
wherein
The linear convolution matrix H for L=0 (no prefix) can in detail be written as H(k,l)=hk-l, k,lε1, . . . , N, wherein N is the block length of the symbol blocks (without any prefixes). The matrix H can be straightforwardly modified to include a prefix of any kind (for example, cyclic, all-zero, pseudo random, etc.) of length L. The matrix H−1 is the inverse of the convolution matrix H.
The circular convolution matrix can in detail be written as
{tilde over (H)}(k,l)=hmod(k-l,N),k,lε1, . . . ,N,
wherein mod(a,b) is an ordinary modulo-b operation of a.
The pre-processing unit 216 is further arranged to calculate a second measure Pisi of intersymbol interference caused by the transmission channel 120. The intersymbol interference measure Pisi is calculated as:
The pre-processing unit is further arranged to decompose the intercarrier interference measure Pici into matrices Q, R and D, wherein Q is unitary (i.e. Q−1=QH), R is an upper triangular matrix with ones the main diagonal and D is a diagonal matrix. Thus, the pre-calculation unit is arranged to calculate the matrices Q, R and D as
QRD{circumflex over (=)}Pici
Methods which can be used for determining the values of the matrices Q, R and D are known in the art. For example, an iterative method is used in determining the matrices Q, R and D.
Accordingly the pre-processing unit 216 is arranged to calculate the intercarrier interference measure Pici, and the intersymbol interference measure Pisi, and the matrices Q, R and D based on the intercarrier interference measure Pici. The pre-processing unit 216 is arranged to feed the intercarrier interference measure Pici, the intersymbol interference measure Pisi and the matrices Q, R and D to the memory unit 217. Input data to the pre-processing unit 216 for performing the above described calculations is in the herein described example the impulse response h of the channel, the length N of the blocks and the length L of the prefix. The coherence time of the channel provides a decision parameter for the updating frequency of the intercarrier interference measure Pici, the intersymbol interference measure Pisi, and accordingly, the matrices Q, R and D. Thus, if the transmission channel is time varying, the estimate of the impulse response h may be updated and the intercarrier interference measure Pici, the intersymbol interference measure Pisi and the matrices Q, R and D may be recalculated based on the time varying characteristics of the transmission channel 120.
In
A first intermediate is assigned as
ξ{circumflex over (=)}x(i).
A second intermediate is computed as
q{circumflex over (=)}QHPisit(i−1).
wherein t(i−1) is the preceding transmission block.
Then, the first intermediate is modified in accordance with the principles below.
The values ξ(k) are computed sequentially starting with k=N down to k=1. When computing ξ(k), the elements ξ(k+1:N) already contain properly precoded values computed in previous steps. The value for ξ(k) is computed as
ξ(k){circumflex over (=)}modM(R(k,k:N)ξ(k:N)+q(k))−R(k,k+1:N)ξ(k+1:N)−q(k), wherein k=N:−1:1
In normal wording, the precoding can be interpreted as follows. First, R(k,k:N)ξ(k:N) is computed, which corresponds to linear predistortion in order to remove intra-block-interference such as intercarrier interference. Then, q(k) is added, which corresponds to linear distortion so as to remove inter-symbol interference.
The modulo operator modM, which is arranged to operate on the sum R(k,k:N)ξ(k:N)+q(k) maps the precoded symbol block into a predetermined range [−M, M]. The modulo operator modM is herein referred to as Tomlinson Harashima precoding. M represents the symbol size per dimension (e.g. M=2 for QPSK). For the sake of simple notation, we consider only square constellations of equal size for all carriers (in a multicarrier system) or for all symbols (in a blocked single carrier system). Extensions for most non-square alphabets and different alphabet sizes on different carriers or symbols are straightforward. The modulo operator modM is in one example defined as
modM(x)=mod((x)+M;2M)−M+j(mod(ℑ(x)+M;2M)−M)
Finally, a vector ξ is determined, that yields a linearly precoded symbols in the range [−M, M]. Accordingly, ξ is obtained by finally removing the component q(k), which corresponds to linear distortion that eliminates intersymbol interference and by removing R(k,k+1:N)ξ(k+1:N), which corresponds to the linear distortion that eliminates intercarrier interference.
ξ(k){circumflex over (=)}modM(R(k,k:N)ξ(k:N)+q(k))−R(k,k+1:N)ξ(k+1:N)−q(k), where
k=N:−1:1. A fourth computation unit 344 is arranged to calculate the transmission block t(i) based on the output from the third computation unit 343. In one example, the transmission block t(i) is computed as
t(i){circumflex over (=)}THQ(Rξ+q)
The transmission block t(i) is then fed to the unit 114 arranged to add a prefix or the transmitter 115, as discussed in relation to
q{circumflex over (=)}QHPisit(i−1)
In
The output of the modulo operator unit 436 is fed to a Hermitian operator unit 337. The Hermitian operator unit 437 is arranged to receive the input signal and provide an output, which is a real-valued signal. In one example, wherein the communication system is a DMT system, the Hermitian operator unit is arranged to provide a real-valued baseband transmit signal. Alternatively, the Hermitian operator is omitted. In one example, the Hermitian operator unit 337 is omitted in an OFDM system.
The operation of the receiver part 430 including the demodulator 433, FEQ 434, matrix D unit 435 and modulo operator unit 436 is in one example with a multicarrier receiver summed up by the following equation:
{circumflex over (X)}(k)=modM((DEWy)(k)),
wherein k=1, . . . N, wherein the modulo operator modM represents the above described Tomlinson-Harashima precoding, wherein D is the diagonal matrix, wherein E is the equalizer and wherein W is the DFT matrix preferably implemented as FFT operation.
In an alternative example, with a single-carrier system, the corresponding operation of the receiver part 430 can be summed up as
{circumflex over (X)}(k)=modM((DWHEWy)(k)).
In
The initialization comprises in a first step 551 collecting information related to an impulse response h of the transmission channel 120, related to a symbol block length N of symbol blocks, which are to be transmitted over the transmission channel and the length L of a cyclic prefix. A preferred choice may be L=0, which yields a prefix-free system. Another choice may be L>0 but, in contrast to state-of-the-art systems, smaller than the dispersion of the channel (a prefix might be useful for synchronization or other reasons not related to channel dispersion).
In a second step 552, a first measure Pici of an intercarrier interference associated to the transmission channel 120 is calculated. The intercarrier interference measure Pici is in one example calculated as:
Pici{circumflex over (=)}TH−1{tilde over (H)}TH,
wherein T is a modulation matrix, H is a linear convolution matrix based on the impulse response h of the transmission channel 120, and {tilde over (H)} is a circular convolution matrix based on the impulse response h of the transmission channel 120.
In a third step 553, the intercarrier interference measure Pici is decomposed into matrices Q, R and D. In one example, the decomposition step 553 involves decomposing the intercarrier interference measure Pici into a unitary matrix Q (i.e. Q−1=QH), into an upper triangular matrix R for example with ones the main diagonal and into a diagonal matrix D. To sum up, in the third step 553, the intercarrier interference measure Pici is in one example decomposed in accordance with the equation
QRD{circumflex over (=)}Pici
Methods which can be used for determining the values of the matrices Q, R and D are known in the art. For example, an iterative method is used in determining the matrices Q, R and D.
In a fourth step 554, a second measure Pisi of an intersymbol interference associated to the transmission channel 120 is calculated. The intersymbol interference measure Pisi is in one example calculated as:
In a fifth step 555, the intercarrier interference measure Pici, the intersymbol interference measure Pisi, and the matrices Q, R and D are stored in a memory available to a precoder for use by said precoder in processing symbol data.
As long as the length N of the symbol blocks is not altered and as long as the impulse response h of the channel and the length J of the guard interval is stable, the pre-processing method 550 does not need to be repeated. However, if it is detected in a sixth step 556, that Pici, Pisi, Q, R and D need to be recalculated, the method 550 is repeated. The herein described steps, shown in
In
ξ(k){circumflex over (=)}modM(R(k,k:N)ξ(k:N)+q(k))−R(k,k+1:N)ξ(k+1:N)−q(k),
for k=N:−1:1, wherein initially ξ is set as ξ{circumflex over (=)}x(i)
and wherein q{circumflex over (=)}QH Pisit(i−1)
In a third step 663, the transmission block t(i) is then determined based on the predistorted symbol block ξ. In one example, the transmission block t(i) is determined by modulating the value for each position k of the predistorted symbol block ξ with a transposed modulation matrix. In one example, the transmission block t(i) is determined as
t(i){circumflex over (=)}THQ(Rξ+q)
In a fourth step 664, the transmission block t(i) determined in the preceding step is then fed to a transmitter for transmission over the transmission channel.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/SE2008/050937 | 8/20/2008 | WO | 00 | 9/1/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/021575 | 2/25/2010 | WO | A |
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20110305267 A1 | Dec 2011 | US |