The present application is a national phase application of PCT Application No. PCT/EP2010/001485, filed on Mar. 10, 2010, and claims priority to German Application No. DE 10 2009 019 894.6, filed on May 4, 2009, the entire contents of which are herein incorporated by reference.
1. Field of the Invention
The invention relates to a method and a device for determining estimated values for transmission symbols within a MIMO-OFDM system.
2. Discussion of the Background
In mobile transmission technology with high transmission rates and with low-to-medium mobility of the terminal equipment, multiple antenna systems (Multiple-Input-Multiple-Output (MIMO)-systems) with multiple access according to the orthogonal-frequency multiplex (Orthogonal-Frequency-Division-Multiplexing (FDM)) are increasingly used. The mobile WIMAX standard IEEE802.16e represents an important standard for MIMO-OFDM systems of this kind.
Regarding the technical background, reference is made to US 2008/0063103 A1, which discloses a method for the correction of Alamonti coded MIMO-OFDM signals.
In particular with transmission systems with four transmission antennas, the “Matrix B” transmission mode has proved successful for test purposes, because only two reception antennas are required. Distribution or coding of the individual data symbols s1,s2,s3,s4, . . . to be transmitted to the four transmission antennas m=1,2,3,4 at each of four successive OFDM symbol timing points l,l+1,l+2,l+3 according to the “Matrix B” transmission mode is illustrated in the table in
In order to estimate the transmitted data symbols within the framework of the decoding of the reception symbols, on the one hand, the coefficients v1,v2,v3,v4 and, on the other hand, the channel-transmission factors of the transmission channels between each transmission antenna and each reception antenna, must be estimated. The estimation of the channel transmission factors is typically implemented on the basis of pilot symbols. For this purpose, either standardized pilot symbols known to the receiver or arbitrary pilot symbols not known to the receiver are used. With a use of arbitrary pilot symbols, the individual channel transmission factors can in fact be correctly estimated in their modulus using currently available “Matrix B” decoding methods. However, with currently available “Matrix B” decoding methods, the individual transmission factors provide an uncertainty of 180° in their phase. Since the individual channel transmission factors and also the individual coefficients for channel coding cannot be accurately determined with regard to their sign using the currently available decoding method, the transmitted data symbols also cannot be determined accurately.
Embodiments of the invention provide a decoding method for a MIMO system with four transmission antennas and with “Matrix B” transmission mode.
Embodiments of the invention provide a method for determining estimated values for data symbols transmitted from each of at least four transmission antennas of a MIMO-OFDM transmission system and by an associated device.
According to the invention, in the case of a MIMO-OFDM transmission system with “Matrix B” coding and additional weighting of the transmission symbols transmitted by each transmission antenna with coefficients, hypotheses are set up for the data symbols transmitted from each of the preferably four transmission antennas, in that the data symbols received from each of the at least two reception antennas, preferably from the precisely two reception antennas, are weighted with possible hypotheses for the channel transmission factors of the transmission channels between the respective transmission antenna and the respective reception antenna and with hypotheses for the coefficients. For each hypothesis set up in this manner for each transmitted data symbol, a metric is set up, and the estimated value for each data symbol transmitted is determined from the hypothesis for the respectively transmitted data symbol which provides the lowest metric.
In one variant, each metric is determined separately for each data symbol transmitted respectively by one transmission antenna at one OFDM symbol timing point. In this context, for every hypothesis determined for each transmitted data symbol, the Euclidian distance from the data symbol of the symbol alphabet disposed nearest in the constellation diagram is calculated. In the case of a “Matrix B” coding, in which, for reasons of redundancy, two of the four transmission antennas respectively are supplied with identical data symbols to be transmitted, only the estimated values of the data symbols transmitted respectively by every second transmission antenna therefore need to be calculated with a metric calculation of this kind. Accordingly, in an advantageous manner, only half the number of hypotheses for the channel transmission factors and half the number of metrics need to be calculated.
In a second variant, each metric is determined via the data symbols transmitted from all of the preferably four transmission antennas at one OFDM symbol timing point. In this context, the Euclidian distance from the data symbols of the symbol alphabet disposed respectively nearest in the constellation diagram is calculated for one hypothesis for the data symbols transmitted respectively by all four transmission antennas. In the second variant, the calculation cost is higher than with the first variant. However, the decoding in the second variant is more robust than in the first variant because of the redundancy.
The positive and the negative value of the transmission factor determinable correctly in each case with regard to the modulus, but not unambiguously determinable only with regard to its sign should be used as hypotheses for the transmission factors associated with each of the individual transmission channels. Since the transmission factors of the transmission channels which are emitted from a common transmission antenna are not determinable with regard to their sign for the same reason, but are identical and can be determined in advance with regard to their modulus, only hypotheses for four transmission factors need to be determined independently of the number of reception antennas.
The values +1 or −1 should be used as hypotheses for the coefficients for the additional channel coding, wherein either only the value +1 or only the value −1 should be set for the coefficients for weighting the data symbols transmitted at every second OFDM symbol timing point.
Accordingly, in a first embodiment of the method according to the invention, a total of 32 hypothesis combinations for which the associated metrics must be determined is obtained. Since, from this total of 32 hypothesis combinations, only 8 hypothesis combinations lead to data symbols in the constellation diagram which are associated with the symbol alphabet used, and since the sign for the estimated values of the data symbols transmitted respectively by the four transmission antennas is not relevant in the case of an amplitude-orientated analysis of the transmission symbols, for example, in the case of a measurement of the amplitude of the error vector (Error Vector Magnitude (EVM)) or of the IQ offset, only one of these 8 hypothesis combinations, which are associated with data symbols of the symbol alphabet needs to be detected in determining the estimated values for the data symbols transmitted by each of the four transmission antennas.
In a second embodiment of the method according to the invention, in order to reduce the number of the total of 32 hypothesis combinations to be determined to a total of 10 hypothesis combinations to be calculated, in addition to limiting the hypotheses for the coefficients for the weighting of the data symbols transmitted respectively at every second OFDM symbol timing point exclusively to the value +1 or exclusively to the value −1, either only positive values of the transmission factor correctly determinable in each case with regard to the modulus should be used for the hypotheses of the transmission factors associated with the individual transmission channels, or a negative value of the transmission factor correctly determinable in each case with regard to the modulus should be used only for a single transmission factor associated with a transmission channel. From the total of 10 hypothesis combinations to be determined in this case, at least one hypothesis combination leads to data symbols in the constellation diagram which are associated with the symbol alphabet used. On the basis of a purely amplitude-orientated analysis of the transmission symbols, only one of these hypothesis combinations which lead to data symbols in the constellation diagram associated with the symbol alphabet used needs to be detected.
The channel transmission factors in the individual sub-carriers and at the individual OFDM symbol timing points of a partial transmission channel are identical, assuming a flat-frequency and time-invariant partial transmission channel, so that, a hypothesis calculation and metric calculation for all possible hypotheses needs to be implemented only for one sub-carrier and for one OFDM symbol timing point of the respective partial transmission channel, typically for the first sub-carrier and for the first OFDM symbol timing point of the respective partial transmission channel, and these results must be transferred to the other sub-carriers and the other OFDM symbol timing points of the respective partial transmission channel.
Embodiments of the method according to the invention and of the device according to the invention for determining estimated values for data symbols transmitted in each case from four transmission antennas of a MIMO-OFDM transmission system are explained in detail in the following section with reference to the drawings. The drawings are as follows:
The following section discusses the mathematical basis required for an understanding of the invention.
According the block-circuit diagram in
A superimposition of the OFDM data symbols xm(u,l) transmitted respectively by all transmission antennas m and an additional additive noise interference wn(u,l) on the basis of the noise in analog components of the reception antenna n occurs in the reception antenna n. The received OFDM data symbol yn(u,l) in the time domain resulting from the superimposition in the reception antenna n is transformed by means of discrete Fourier transform (DFT) into the receiving data symbol rn(u,l) in the frequency domain.
For the MIMO-OFDM transmission system illustrated in
A MIMO-OFDM transmission system, which is equivalent to the MIMO-OFDM transmission system in
For the MIMO-OFDM transmission system illustrated in
Starting from equation (2), with a “Matrix B” coding according to the table in
In equations (3A) and (3B) and respectively (4A) and (4B), the abbreviation hnm for the transmission factor hnm(k) in equation (2) has been introduced, and the conjugated complex coefficient vi* has been replaced by the coefficient vi in view of the fact that it is real.
As is evident from equations (3A) and (3B) and respectively (4A) and (4B), in order to determine the 4 OFDM data symbols {right arrow over (S)}1-4 and respectively {right arrow over (S)}5-8 transmitted with known transmission factors hnm and with known coefficients vi, at least two reception antennas 1,2 are required. According to equation (5A) and (5B) and respectively equation (6A) and (6B), the OFDM data symbols {right arrow over (r)}1-4 and respectively {right arrow over (r)}5-8 received by the two reception antennas 1,2 at the OFDM symbol timing points l and l+1 and l+2 and l+3 are obtained.
{right arrow over (r)}
5-8
=V
34
·H
5-8
·{right arrow over (S)}
5-8 (6B)
To determine the matrix elements of the channel matrices H1-4 and respectively H5-8 , in equation (5B) and respectively (6B), an estimation matrix with estimated transmission factors ĥnm is required. For a MIMO-OFDM transmission system with respectively four transmission antennas and four reception antennas, an estimation matrix of this kind is obtained according to equation (7)
The determination of the estimated values ĥnm for the individual transmission factors hnm is implemented on the basis of pilot symbols. If the pilot symbols used are standardized, then they are known to the receiver and, from the transmitted pilot symbol known to it, and the received pilot symbol corresponding to the known transmitted pilot symbol, the receiver can correctly determine the estimated value ĥnm for the associated transmission factor hnm with regard to modulus and sign.
If arbitrary, non-standardized pilot symbols are used, preferably BPSK-modulated pilot symbols, the modulus of the estimated value ĥnm for the associated transmission factor hnm can indeed be determined by the receiver, but, because the receiver does not know whether a BPSK modulated pilot symbol +1 or a BPSK-modulated pilot symbol −1 has been transmitted, uncertainty exists regarding the sign or the phase of the estimated value ĥnm for the associated transmission factor hnm. This uncertainty about the sign of the estimated value ĥnm for the associated transmission factor hnm is identical for all transmission factors hnm which relate to the same transmission antenna, because of the pilot symbol transmitted identically from the same transmission antenna to all reception antennas. Accordingly, the estimated values ĥnm for the transmission factors hnm of one column of the estimation matrix provide the same sign and differ only in their respective moduli. In the individual sub-frequency carriers of the transmission channel from a transmission antenna to a reception antenna, the estimated value ĥnm for the associated transmission factor hnm is identical with regard to sign and modulus because of the flat-frequency partial channels.
In the case of unknown coefficients v1,v2,v3,v4, hypotheses {tilde over (v)}1,{tilde over (v)}2,{tilde over (v)}3,{tilde over (v)}4 for the unknown coefficients v1,v2,v3, v4 are set up. With these hypotheses {tilde over (v)}1,{tilde over (v)}2,{tilde over (v)}3,{tilde over (v)}4 for the unknown coefficients v1,v2,v3,v4, the received OFDM data symbols {right arrow over (r)}1-4 and respectively {right arrow over (r)}5-8 are weighted according to equations (8A) and (8B) and respectively equation (9A) and (9B).
The channel-decoded hypotheses {tilde over ({right arrow over (r)}1-4 and respectively {tilde over ({right arrow over (r)}5-8 for the received OFDM data symbols {right arrow over (r)}1-4 and {right arrow over (r)}5-8, channel-decoded according to equations (8A) and (8B) and equations (9A) and (9B) from the weighting of the received data symbols {right arrow over (r)}1-4 and respectively {right arrow over (r)}5-8 with the hypotheses {tilde over (v)}1,{tilde over (v)}2,{tilde over (v)}3,{tilde over (v)}4 for the unknown coefficients v1,v2, v3,v4, are equalised in the case of estimated values ĥn1,ĥn2,ĥn3,ĥn4 for the transmission factors hn1,hn2,hn3,hn4, known with regard to the modulus but unknown with regard to the sign, of the partial channels extending from the four transmission antennas 1,2,3,4 to the respectively n reception antennas, in each case according to equation (10) and (11) with the hypothesis matrices 1-4 and respectively 5-8 for the channel transmission matrices H1-4 and respectively H5-8, in order to determine hypotheses {tilde over ({right arrow over (S)}1-4 and respectively {tilde over ({right arrow over (S)}5-8 for the transmitted OFDM symbols {right arrow over (S)}1-4 and {right arrow over (S)}5-8. The hypothesis matrices 1-4 and respectively 5-8 each contain hypotheses {tilde over (h)}n1,{tilde over (h)}n2,{tilde over (h)}n3,{tilde over (h)}n4 for the transmission factors hn1,hn2,hn3,hn4 in the partial channels between the four transmission antennas and the n=1, . . . , NR reception antennas, wherein NR is the number of reception antennas. Accordingly, the two values +ĥnm and −ĥnm are selected for the hypotheses {tilde over (h)}n1,{tilde over (h)}n2,{tilde over (h)}n3,{tilde over (h)}n4 for the transmission factors hn1,hn2,hn3,hn4 on the basis of the knowledge of the modulus of the estimate of the respective transmission factor and on the basis of the uncertainty about the sign of the estimate of the respective transmission factor, wherein ĥnm is the known modulus of the estimated value of the respective transmission factor. Conversely, since the estimated transmission factors ĥnm assume ĥnm−±hnm in view of the uncertainty in the channel estimation,
applies for the hypothesis {tilde over (h)}nm of the respective transmission factor, taking into consideration {tilde over (h)}nm=±ĥnm.
{tilde over ({right arrow over (S)}1-4=1-4−1·{tilde over ({right arrow over (r)}1-4 (10)
{tilde over ({right arrow over (S)}1-4=5-8−1·{tilde over ({right arrow over (r)}5-8 (11)
If the mathematical relationships for the channel-decoded hypotheses {tilde over ({right arrow over (r)}1-4 and respectively {tilde over ({right arrow over (r)}5-8 for the received OFDM data symbols {right arrow over (r)}1-4 and {right arrow over (r)}5-8 from equations (8B) and (9B) and the mathematical relationships for the received data symbols {right arrow over (r)}1-4 and respectively {right arrow over (r)}5-8 from equations (5B) and (6B) are inserted into equation (10) and respectively (11), equations (12) and respectively (13) are obtained.
{tilde over ({right arrow over (s)}1-4=11-4··{right arrow over (r)}1-4=11-4··V12·H1-4·{right arrow over (s)}1-4 (10)
{tilde over ({right arrow over (s)}−15-84·{right arrow over (r)}5-8=15-8·4·V34·H5-8·{right arrow over (s)}5-8 (11)
If the hypotheses {tilde over (v)}i for the coefficients vi agree with the actual coefficients vi, and the hypotheses {tilde over (h)}nm for the transmission factors hnm agree with the actual transmission factors hnm then the hypotheses {tilde over ({right arrow over (s)}1-4 and respectively {tilde over ({right arrow over (s)}5-8 for the transmitted OFDM data symbols {right arrow over (s)}1-4 and {right arrow over (s)}5-8 according to equation (12) and respectively (13) agree with the actually transmitted OFDM data symbols {right arrow over (s)}1-4 and respectively {right arrow over (s)}5 8 and form the estimated values {tilde over ({right arrow over (s)}1 4 and {tilde over ({right arrow over (s)}5-8 for the transmitted OFDM data symbols {right arrow over (s)}1-4 and respectively {right arrow over (s)}5-8.
If every hypothesis {tilde over (v)}i for the coefficients vi and every hypothesis {tilde over (h)}nm for the transmission factor hnm is combined with one another, a total of 64 hypothesis combinations are obtained. The decoding of the received OFDM data symbols {right arrow over (r)}1-4 and respectively {right arrow over (r)}5-8 according to equation (10) and respectively (11) in order to obtain the associated hypotheses {circumflex over ({right arrow over (s)}1-4 and {circumflex over ({right arrow over (s)}5-8 for the transmitted OFDM data symbols {right arrow over (s)}1-4 and {right arrow over (s)}5-8 is implemented separately with every individual hypothesis combination from the total of 64 hypothesis combinations. If the decoding is implemented with all 64 hypothesis combinations, the decoding results presented in the table in
The table in
Accordingly, only those right-hand table elements contain a value at which a singular and linear dependence between the respective hypothesis si of the transmitted OFDM symbol si and the associated, actually transmitted OFDM symbol si exists, which can differ only with regard to the sign. In all other cases, in which the respective table element is blank, the respective hypotheses {tilde over (s)}i of the transmitted OFDM symbol si provides a more complex functional connection with one or more transmitted OFDM symbol si. While, in the first case, the respective hypothesis {tilde over (s)}i of the transmitted OFDM symbol si coincides with an OFDM data symbol of the symbol alphabet used in the constellation diagram, which can differ from the actually transmitted OFDM symbol si only with regard to the sign, in the second case, the respective hypothesis {tilde over (s)}i of the transmitted OFDM symbol si does not come to be disposed on any OFDM data symbol of the symbol alphabet used in the constellation diagram and is therefore excluded as a hypothesis combination which can be used for the decoding.
Additionally, it must be established that, with a value of −1 for the product {tilde over (v)}1·v1 of the hypothesis {tilde over (v)}1 for the coefficient v1 and the actual coefficient v1 and at the same time with a value of +1 for the product {tilde over (v)}2·v2 of the hypothesis {tilde over (v)}2 for the coefficient v2 and the actual coefficient v2 for the hypothesis {tilde over (s)}i of the transmitted OFDM symbol si, the associated transmitted OFDM data symbol ±si, which is identical with regard to modulus and differs possibly only with regard to sign, is determined as in the case of a value of +1 for the product {tilde over (v)}1·v1 of the hypothesis {tilde over (v)}1 for the coefficient vl and the actual coefficient vl and at the same time with a value of −1 for the product {tilde over (v)}2·v2 of the hypothesis {tilde over (v)}2 for the coefficient v2 and the actual coefficient v2.
Moreover, it must be established that with a value of −1 for the product {tilde over (v)}v·v1 of the hypothesis {tilde over (v)}1 for the coefficient v1 and the actual coefficient v1 and at the same time with a value of −1 for the product {tilde over (v)}2·v2 of the hypothesis {tilde over (v)}2 for the coefficient v2 and the actual coefficient v2 for the hypothesis {tilde over (s)}i of the transmitted OFDM symbol si, the same transmitted OFDM data symbol ±si, which is identical with regard to modulus and differs possibly only with regard to sign, is determined as with a value of +1 for the product {tilde over (v)}1·v1 of the hypothesis {tilde over (v)}1 for the coefficient v1 and the actual coefficient v1 and at the same time with a value of +1 for the product {tilde over (v)}2·v2 of the hypothesis {tilde over (v)}2 for the coefficient v2 and the actual coefficient v2. The same results are obtained for the product {tilde over (v)}3·v3 of the hypothesis {tilde over (v)}3 for the coefficient v3 and the actual coefficient v3 and for the product {tilde over (v)}4·v4of the hypothesis {tilde over (v)}4 for the coefficient v4 and the actual coefficient v4.
Since the sign of the decoded OFDM data symbol ŝi is not relevant in the case of an amplitude-orientated analysis of the transmitted OFDM data symbols, in a first embodiment of the invention, the number of hypothesis combinations can be reduced from originally 64 hypothesis combinations to 32 hypothesis combinations by investigating respectively either only the value +1 or only the value −1 for the product {tilde over (v)}1·v1 and the product {tilde over (v)}3·v3, as shown in the table in
For the hypothesis combinations with an even hypothesis-combination number in the table in FIG. 5—in the table in
As is evident from the table in
In order to identify one of the 8 correct hypothesis combinations, according to equations (14A) and respectively (14B), a metric is calculated in each case, which determines the Euclidian distance between the determined hypotheses {tilde over (s)}i for every transmitted OFDM data symbol si and the associated OFDM data symbol di of the symbol alphabet used which is disposed nearest in the constellation diagram.
As an alternative, the metric according to equation (15) can be calculated separately for every OFDM data symbol si as the Euclidian distance between the hypothesis {tilde over (s)}i determined for each transmitted OFDM data symbol si and the associated data symbol di of the symbol alphabet used which is disposed nearest in the constellation diagram.
Metric=|{tilde over (s)}i−di|∀i=1, . . . , 8 (15)
To achieve an additional reduction in the number of hypothesis combinations to be calculated, it is necessary, through skilled selection of the individual hypotheses {tilde over (h)}nm for the respective transmission factor hnm which is not known to the receiver, to find at least one of the 8 hypothesis combinations, which, in each case, in the table in
From the table in
scaled to the actual transmission factor each provide a value +1 or respectively a value −1, or respectively, two scaled hypotheses
each provide a value +1 and respectively two scaled hypotheses
each provide a value −1. Consequently, for all value combinations of the actual transmission factors, corresponding hypotheses {tilde over (h)}nm for the individual transmission factors hnm must be selected, so that at least one of these 8 hypothesis combinations of the scaled hypotheses
is obtained which, for every transmitted OFDM data symbol si, leads to a hypothesis {tilde over (s)}i, which, ignoring the sign of the hypothesis {tilde over (s)}i, leads to an OFDM symbol of the symbol alphabet used.
It is simplest if the ratios of the estimated to the actual transmission factors are either all positive (that is ĥnm=+hnm) or all negative (that is ĥnm=−hnm), or two ratios are positive in each case (that is ĥnm=+hnm) and two ratios are negative in each case (that is ĥnm=−hnm). Accordingly, in each case, a positive estimated value +ĥnm for the transmission factor hnm is assigned to the hypothesis {tilde over (h)}nm for each of the transmission factors (see lines 1 and 2 in the table in
are obtained as
If the ratio of the estimated transmission factor to the actual transmission factor is a positive value ĥnm=+hnm, a value of +1 is obtained for the associated scaled hypothesis
and, if the ratio is a negative value ĥnm=−hnm, a value of −1 is obtained for the associated scaled hypothesis
The signs of the ratios of the estimated transmission factors and the actual transmission factors are consequently retained in the signs of the associated scaled hypotheses
and therefore lead to one of the 8 hypothesis combinations in the table in
In all other cases, if only a single ratio is positive (that is ĥnm=+hnm) and the other three ratios are each negative (that is ĥnm=−hnm), or only a single ratio is negative (that is ĥnm=−hnm) and the other three ratios are each positive (that is ĥnm=+hnm), in each case, a negative estimated value −ĥnm for the transmission factor hnm is assigned to the hypothesis {tilde over (h)}nm for a single transmission factor hnm, and in each case, a positive estimated value +ĥnm for the transmission factor hnm is assigned to the hypotheses {tilde over (h)}nm for the other three transmission factors hnm (see lines 3 to 10 in the table in
If the hypothesis {tilde over (h)}nm for the transmission factor hnm, to which a negative estimated value −ĥnm for the transmission factor hnm is assigned, coincides with an estimated value with a negative ratio (that is ĥnm=−hnm), a value of +1 is obtained for the associated scaled hypothesis
while, for the other actual transmission factors hnm of which the ratios are accordingly positive (that is ĥnm=+hnm), a hypothesis {tilde over (h)}nm with a positive estimated value +ĥnm is assigned, which leads to a scaled hypothesis
Accordingly, through this assignment of the hypothesis {tilde over (h)}nm, one of the total of 8 hypothesis combinations in the table in
By contrast, if the hypothesis {tilde over (h)}nm for the transmission factor hnm to which a negative estimated value −ĥnm for the transmission factor hnm is assigned, coincides with a positive ratio (that is ĥnm=+hnm), a value of −1 is obtained for the associated scaled hypothesis
while, for the other actual transmission factors hnm a hypothesis {tilde over (h)}nm with a positive estimated value +ĥnm is assigned. For the two actual transmission factors hnm, of which the ratios are positive (that is ĥnm=+hnm), the scaled hypothesis
with the value +1 is obtained, while, for the single actual transmission factor hm of which the ratio is negative (that is ĥnm=−hnm), the scaled hypothesis
with a value −1 is obtained.
Accordingly, through this assignment of the hypothesis {tilde over (h)}nm, one of the total of 8 hypothesis combinations in the table in
In the second embodiment of the invention, as with the first embodiment of the invention in the table in
In the following section, the method according to the invention for determining estimated values for data symbols transmitted in each case from four transmission antennas of a MIMO-OFDM transmission system is explained with reference to the flow chart in
In the first method step S10, hypotheses {tilde over ({right arrow over (s)}1-4 and respectively {tilde over ({right arrow over (s)}5-8 for the OFDM data symbols e,rar s1-4 and {right arrow over (s)}5-8 transmitted at each OFDM symbol timing point l,l+1,l+2,l+3, . . . are calculated by the receiver according to equations (10) and respectively (11) at every OFDM symbol timing point, starting from the OFDM symbols {right arrow over (r)}1-4 and respectively {right arrow over (r)}5-8 received by the two reception antennas in each case at the respective OFDM symbol timing point l,l+1,l+2,l+3, . . . In this context, hypotheses {tilde over (v)}1, {tilde over (v)}2, {tilde over (v)}3, {tilde over (v)}4 for the unknown coefficients v1, v2, v3, v4 for the additional channel coding of the transmitted OFDM data symbols {right arrow over (s)}1-4 and respectively {right arrow over (s)}1-4 within the framework of the “Matrix B” coding, and hypotheses {tilde over (h)}n1,{tilde over (h)}n2,{tilde over (h)}n3,{tilde over (h)}n4 for the transmission factors hn1,hn2,hn3,hn4 of the individual partial channels between the four transmission antennas m and the at least two reception antennas n in the framework of the total of 32 hypothesis combinations of the first embodiment of the invention in table in
In the next method step S20, a metric is calculated for each of the 32 or respectively 10 hypothesis combinations. In a first variant, according to equations (14A) and respectively (14B), the metric is determined as a summated Euclidian distance between the hypotheses {tilde over (s)}i of respectively four transmitted OFDM data symbols si and the associated OFDM data symbols of the symbol alphabet used which are disposed nearest in the constellation diagram. In a second variant, according to equation (15), the metric is determined separately for every transmitted OFDM data symbol si as the Euclidian distance between the hypothesis {tilde over (s)}i of the respective transmitted OFDM data symbol si and of the associated OFDM data symbol of the symbol alphabet used which is disposed nearest in the constellation diagram. In this context, it is sufficient that the metric is implemented according to equation (15) only for one of the four transmitted data symbols s1 to s4 and only for one of the four transmitted data symbols s5 to s8. This has the advantage that the cost for the calculation of the metric(s) is reduced to a quarter, while the robustness of the metric is disadvantageously reduced.
In the last method step S30, the hypothesis {tilde over (s)}i of the transmitted OFDM data symbols si is finally selected as an estimated value ŝi of the transmitted OFDM data symbol si, which provides the lowest metric in each case. Accurately, only one of the 8 hypothesis combinations of the table in
The invention is not restricted to the embodiments and variants of the invention presented. In particular, MIMO-OFDM transmission systems with more than two reception antennas are also covered by the invention.
Number | Date | Country | Kind |
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10 2009 019 894 | May 2009 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2010/001485 | 3/10/2010 | WO | 00 | 11/4/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/127736 | 11/11/2010 | WO | A |
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