JP3905045B2 - Space division multiplexing OFDM receiver - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a receiver for packet communication used in a space-division-multiplexed OFDM (Orthogonal Frequency Division Multiplexing) type digital wireless communication system, and more particularly to a receiver capable of performing efficient selective diversity reception.
[0002]
[Prior art]
In space division multiplexing, a plurality of different data sequences are simultaneously transmitted from a plurality of antennas using the same frequency, signals are received by a plurality of receiving antennas in a receiving apparatus, and propagation paths (from each transmitting antenna to each receiving antenna ( This is a method of extracting each data series by estimating a transmission signal based on a transfer function estimation result for each channel). Since the space division multiplexing method is a method in which the transmission rate per frequency is multiplied by the number of transmission antennas, the transmission rate can be increased in a limited frequency band.
[0003]
In addition, when applied to high-speed communication, the space division multiplexing scheme increases the number of symbols that cause intersymbol interference due to the influence of delayed waves, and increases exponentially by increasing the number of symbols that correct the effect of intersymbol interference. The amount of calculation increases.
[0004]
However, when space division multiplexing is applied to OFDM, intersymbol interference due to delayed waves can be avoided, so that an increase in the amount of computation can be suppressed and high-speed transmission can be realized. Further, in the space division multiplexing scheme, when the number of transmission antennas is constant, the error rate characteristic is improved by the reception diversity effect as the number of reception antennas is increased. When demodulation is performed using all the reception signals from the reception antennas whose number is increased, the arithmetic processing for demodulating the space division multiplexed signal becomes large. However, when selection diversity is applied, an increase in circuit scale can be suppressed and diversity gain can be obtained.
[0005]
As conventional selection diversity reception, there is known a method of selecting a reception system having a high reception signal level in order to improve the SNR of a signal. A conventional space division multiplexing OFDM receiver will be described with reference to FIG. FIG. 7 is a block diagram of a conventional space division multiplex OFDM receiver, and a conventional space division multiplex OFDM receiver to which selection diversity for selecting a received signal based on the magnitude of the received signal level of the space division multiplex OFDM signal is applied. A configuration example is shown. This example assumes a case where there are two transmission antennas and three reception antennas, and two received signals are selected from three received signals and demodulated.
[0006]
In FIG. 7, the spatial division multiplexed OFDM signals received by the antennas 1-1, 1-2, and 1-3 are respectively received by the receiving circuits 2-1, 2-2, and 2-3 and the received power detecting circuit 3-1. Input to 3-2 and 3-3. Receiving circuits 2-1, 2-2 and 2-3 respectively perform frequency conversion, automatic gain control (AGC), filtering and analogy on the input spatial division multiplexed signals. NALOG Necessary reception processing such as digital conversion, symbol timing detection and carrier frequency synchronization is performed, and a complex baseband reception signal is output. The complex baseband reception signals output from the reception circuits 2-1, 2-2 and 2-3 are input to the multi-input / multi-output selection circuit 5.
[0007]
The reception power detection circuits 3-1, 3-2, and 3-3 detect the reception signal power of the input space division multiplexed OFDM signal and output it to the comparison circuit 4. The comparison circuit 4 compares the magnitudes of the input received signal powers and outputs comparison result information. The comparison result information output from the comparison circuit 4 is input to the multi-input / multi-output selection circuit 5. Based on the comparison result information input from the comparison circuit 4, the multi-input / multi-output selection circuit 5 receives received power from the three complex baseband received signals input from the receiving circuits 2-1, 2-2, and 2-3. Selects and outputs two complex baseband received signals with large values. The two complex baseband received signals output from the multi-input multi-output selection circuit 5 are input to the Fourier transform circuits 6-1 and 6-2, respectively.
[0008]
The Fourier transform circuits 6-1 and 6-2 perform processing such as guard interval removal on the input complex baseband received signal, perform Fourier transform, and output a space division multiplexed subcarrier signal. The spatial division multiplexed subcarrier signals output from the Fourier transform circuits 6-1 and 6-2 are input to the channel estimation circuits 7-1 and 7-2 and the spatial division multiplexed signal separation circuit 8, respectively.
[0009]
Channel estimation circuits 7-1 and 7-2 estimate the transfer function representing the state of the propagation path (channel) for each transmission antenna for each subcarrier using the respective spatial division multiplexed subcarrier signals, and are estimated. The transfer function of each subcarrier is output. Due to fading, each signal between each transmitting antenna and each receiving antenna receives a different amplitude / phase variation (transfer function), but a known reference signal for channel estimation is transmitted and prepared on the receiving side. By comparing with a known ideal signal, the transfer function of each channel can be estimated.
[0010]
The transfer functions of the subcarriers output from the channel estimation circuits 7-1 and 7-2 are input to the space division multiplex signal separation circuit 8, respectively. The space division multiplex signal separation circuit 8 includes a transfer function of each subcarrier input from the channel estimation circuits 7-1 and 7-2 and a space division multiplex subcarrier signal input from the Fourier transform circuits 6-1 and 6-2. Are used to estimate the subcarrier modulation signals transmitted from the two transmission antennas, respectively, and output two subcarrier modulation signals. The two subcarrier modulation signals output from the spatial division multiplexing signal separation circuit 8 are input to the parallel-serial conversion circuit 9.
[0011]
The parallel-serial conversion circuit 9 performs parallel-serial conversion on the two input parallel subcarrier modulation signals and outputs the result. The subcarrier modulation signal output from the parallel / serial conversion circuit 9 is input to the subcarrier demodulation circuit 10. The subcarrier demodulation circuit 10 demodulates the input subcarrier modulation signal, and outputs a bit string obtained as a result of the demodulation (see, for example, Non-Patent Document 1).
[0012]
[Non-Patent Document 1]
Yoichi Saito, “Modulation and Demodulation of Digital Wireless Communication,” edited by the Institute of Electronics, Information and Communication Engineers, ISBN 4-88552-135-1, February 10, 1996, lines 189 pages 14-22 and page 190, page 5.19 (a) “ “Selective combining” described in “5.3.3 Diversity reception (1) Branch combining method”
[0013]
[Problems to be solved by the invention]
In general, when performing selective diversity reception for each packet in packet communication, in order to improve the SNR of the received signal, the reception system is selected based on the received power of the preamble signal portion added to the head of the packet. Is called. In space division multiplexing, a plurality of different modulated signal sequences are simultaneously transmitted from a plurality of transmitting antennas using the same frequency, and a receiver receives a space division multiplexed signal in which a plurality of different modulated signals are superimposed on a radio propagation path. The The received space division multiplexed signal estimates a transfer function between the respective transmitting and receiving antennas, and is separated into modulated signals transmitted from the respective transmitting antennas based on the estimated transfer function. After separation, each modulated signal is demodulated.
[0014]
In the space division multiplexing method, even when the transmission signal from each transmission antenna is independently received with high power (when the power of each transfer function is large), the space division multiplexing of the preamble signal portion for detecting the reception power is performed. The signal power may be reduced depending on the combination of phases when the transmission signals are superimposed. Therefore, when a reception system is selected based on the received signal power of the space division multiplex signal, there is a problem that the diversity gain of selection diversity cannot be obtained sufficiently.
[0015]
Therefore, the present invention calculates the power of the transfer function between the transmitting and receiving antennas and applies the sum of the powers of the transfer functions of the transmitting antennas for each receiving system when applying selection diversity in the space division multiplexing OFDM receiver. By calculating the sum of received power of all subcarriers in all receiving system combinations and maximizing the sum of received power of all subcarriers as a criterion for selecting the receiving system, An object of the present invention is to provide a space division multiplexing OFDM receiver capable of improving the gain of selection diversity and improving the error rate characteristics.
[0016]
[Means for Solving the Problems]
The present invention is a space division multiplexing OFDM receiver, in which L (L> 0: integer) transmission antennas simultaneously transmitted from L transmission systems using the same frequency are overlapped on a radio propagation path. M (M> 0: integer) receiving means for receiving and receiving the division multiplexed OFDM signals, and M received power detections for receiving the spatial division multiplexed OFDM signals and detecting their received power And N (0 <N <M: integer) received signals output from the first multi-input / multi-output selecting means, respectively, are subjected to Fourier transform, and are separated into spatial division multiplexed signals for each subcarrier, respectively. N Fourier transform means for outputting a plurality of spatial division multiplexed subcarrier signals, and each of the subcarriers using each spatially separated multiplexed subcarrier signal output by the N Fourier transform means. N channel estimation means for estimating a transfer function for each transmission antenna, and spatial division multiplexed subcarrier signals output by the N Fourier transform means are output from the N channel estimation means. Space division multiplexed signal demultiplexing means for separating into L subcarrier modulation signals respectively transmitted from the L transmission antennas using the transfer function estimation result of each subcarrier, and output from the space division multiplexed signal demultiplexing means And a sub-carrier demodulating means for demodulating the sub-carrier modulation signal.
[0017]
Here, a feature of the present invention is that the L transmission antennas and the respective reception antennas are based on reception signals output from the M reception units and reception power output from the M reception power detection units. M transfer function power detection means for calculating the sum of the powers of L transfer functions between the L transfer functions, and the sum of the powers of the L transfer functions output from the M transfer function power detection means, respectively. First comparison means for comparing the magnitudes and outputting the comparison result information, wherein the first multi-input / multi-output selection means comprises the M of the reception signals output from the reception means. There is provided means for selecting and outputting N (N <M: integer) received signals in descending order of the sum of the powers of the L transfer functions based on the output of the first comparing means. Corresponds to item 1).
[0018]
In general, when performing selective diversity reception, a reception sequence that improves the SNR of a received signal is selected. In a communication system that does not perform space division multiplexing communication, the SNR of the received signal can be improved with high accuracy by selecting a receiving system having a high power level of the received signal.
[0019]
However, in the conventional space division multiplexing OFDM receiver described above, signals are received in a state in which transmission signals from a plurality of transmission antennas are superimposed on a radio propagation path, so that when each transmission signal is received alone Even when the received signal power is at a high level, the received power of the spatial division multiplexed signal in the preamble signal part for detecting power may be reduced by canceling each other's signals due to the phase shift when the transmitted signal is superimposed. is there. On the contrary, when the transmission signals are superimposed on each other in phase, reception signal power higher than when each transmission signal is received alone may be detected.
[0020]
Therefore, when the reception system is selected based on the reception power of the space division multiplexed OFDM signal, it does not reflect the reception power in a state where the space division multiplexed OFDM signal is separated into a plurality of transmission signals. There was a problem that the gain was insufficient.
[0021]
According to the space division multiplexing OFDM receiver of the present invention, the criterion for selecting a reception system in selective diversity reception is based on the sum of the powers of the transfer functions of the transmission antennas for each reception system. In a certain reception system, the power of the transfer function with each transmission antenna represents the reception power when a signal is transmitted independently from each transmission antenna.
[0022]
Therefore, the power of the transfer function reflects the received power in a state where the space division multiplexed OFDM signal is separated into OFDM signals transmitted from the respective transmission antennas. That is, by selecting a receiving system based on the received power in a state where the space division multiplexed OFDM signal is separated into OFDM signals transmitted from the respective transmitting antennas, the gain of selection diversity is improved, and the SNR of the received signal is increased. The reception system to be improved is selected, and the error rate characteristics of the space division multiplexing OFDM receiver can be improved.
[0023]
Further, the transfer function power detection means outputs a first delay means for delaying a reception signal output from the reception means for a predetermined time, a reception signal output from the reception means, and an output from the first delay means. First adding means for adding to the delayed signal, and first subtracting means for calculating a difference between the received signal output from the receiving means and the delayed signal output from the first delay means A first square means for squaring the output of the first addition means, a second square means for squaring the output of the first subtraction means, and an output of the first square means for a predetermined value A first averaging means for averaging over the number of samples; a second averaging means for averaging the output of the second square means over a predetermined number of samples; the output of the first averaging means and the second averaging means Second addition means for adding the output of It may comprise a first multiplying means for multiplying the received electric power output from the reception power detecting means to the output of the second adding means (corresponding to claim 2).
[0024]
Alternatively, the transfer function power detection means includes a third square means for squaring the reception signal output from the reception means, and a third average means for averaging the output of the third square means over a predetermined number of samples. Second delay means for delaying the output of the third averaging means for a predetermined time; and third addition means for adding the output of the second delay means and the output of the third average means The second addition means for multiplying the output of the third addition means and the reception power output from the reception power detection means can be provided (corresponding to claim 3).
[0025]
Alternatively, the space division multiplexing OFDM receiver of the present invention is a space in which L different OFDM signal sequences simultaneously transmitted from L (L> 0: integer) transmission antennas using the same frequency are superimposed on a radio propagation path. M (M> 0: integer) receiving means for receiving and receiving the division multiplexed OFDM signals, and M received power detections for receiving the spatial division multiplexed OFDM signals and detecting their received power And the preamble signal portion added to the head of the packet of the received signal output from the M receiving means outputs the received M system received signals to the first to M-th Fourier transform means, respectively. The data signal portion following the portion selects N (N <M: integer) received signals from the input M received signals based on the output of the second comparing means. Output switching means for outputting to N Fourier transform means, and the M number of Fourier transform means separate the received signals output from the output switching means into space division multiplexed signals for each subcarrier using Fourier transform. And a means for outputting a predetermined space division multiplexed subcarrier signal, and for each of the transmission antennas of each subcarrier using the N systems of space division multiplexed subcarrier signals output from the second multi-input / multi-output selection means. N channel estimation means for estimating a transfer function of the sub-carrier signals, and the spatial division multiplexed subcarrier signals output by the first to N-th Fourier transform means are used as sub-channels output from the N channel estimation means. Spatial division for separating into L subcarrier modulation signals respectively transmitted from the L transmission antennas using a carrier transfer function estimation result And weight signal separating means, a space division multiplexing OFDM receiver including a sub-carrier demodulation means for demodulating the subcarrier modulation signal output from the space division multiplexing signal separation means.
[0026]
Here, a feature of the present invention is that there are M systems using each spatial division multiplexed subcarrier signal output from the M number of Fourier transform means and received power output from the M number of received power detection means. Subcarrier power calculating means for calculating the sum of the received power of all subcarrier signals in all combinations when N received signals are selected from the received signals of the second, and the second comparing means includes the subcarrier power. Means for comparing the outputs of the arithmetic means and outputting combination information of N systems of received signals that maximizes the sum of the received power of all subcarrier signals, and the second multi-input multi-output selecting means comprises the first Based on the combination information of the N systems of received signals output from the two comparison means, M systems of space division multiplexed subcarrier signals output from the M Fourier transform means It is in place and a second multiple-input multiple-output selecting means selects and outputs the space division multiplexing sub-carrier signals of Luo N systems (corresponding to claim 4).
[0027]
According to the spatial division multiplexing OFDM receiver of the present invention, the criterion for selecting a reception system in selective diversity reception is the sum of the received powers of all subcarriers after the spatial division multiplexing subcarrier signal is separated. Based on. Each space division multiplexed subcarrier signal is demodulated after separating the space division multiplexed subcarrier signal into subcarrier modulation signals transmitted from the respective transmission antennas. The combination of two received signals that maximizes the sum of the received powers of all subcarriers of the subcarrier modulation signal is a combination that improves the SNR in the subcarrier modulation signal. That is, by selecting a combination of receiving systems that maximizes the sum of received powers of modulated signals of all subcarriers, the gain of selection diversity is improved, and the SNR of the subcarrier modulated signal after space division multiplexing subcarrier signal separation is improved. Is selected, and the error rate characteristic of the space division multiplexing OFDM receiver can be improved.
[0028]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
A space division multiplexing OFDM receiver according to the first embodiment will be described with reference to FIG. FIG. 1 is a block diagram of a space division multiplexing OFDM receiver according to the first embodiment (corresponding to claim 1). This figure assumes a case where there are two transmission antennas and three reception antennas, and two received signals are selected from three received signals and demodulated.
[0029]
As shown in FIG. 1, the space division multiplexing OFDM receiver of the first embodiment superimposes two different OFDM signal sequences simultaneously transmitted from two transmitting antennas using the same frequency on a radio propagation path. Three receiving circuits 102-1 to 102-3 that receive the space division multiplexing OFDM signals and perform reception processing, and three reception power detection circuits that receive the space division multiplexing OFDM signals and detect their received power 103-1 to 103-3 and the two received signals output from the multi-input multi-output selection circuit 105 are subjected to Fourier transform to be separated into spatial division multiplexed signals for each subcarrier, and predetermined spatial division multiplexed subcarrier signals. Fourier transform circuits 106-1 and 10-2 that output the signal, and the spatial demultiplexing multiplexers output by the two Fourier transform circuits 106-1 and 10-2. Spatial division output by the two channel estimation circuits 107-1 and 102, and the two Fourier transform circuits 106-1 and 102, each of which estimates the transfer function for each transmission antenna of each subcarrier using the carrier signal. Two subcarrier modulation signals respectively transmitted from the two transmitting antennas by using the transfer function estimation result of each subcarrier output from the two channel estimation circuits 107-1 and 2 from the multiplexed subcarrier signal This is a spatial division multiplexing OFDM receiver comprising: a spatial division multiplexing signal separation circuit 108 that separates the subcarrier modulation signal; and a subcarrier demodulation circuit 110 that demodulates the subcarrier modulation signal output from the spatial division multiplexing signal separation circuit 108.
[0030]
Here, the feature of the first embodiment is based on the reception signals output from the three reception circuits 102-1 to 102-3 and the reception power output from the three reception power detection circuits 103-1 to 103-3. Three transfer function power detection circuits 111-1 to 111-3 for calculating the sum of powers of two transfer functions between the two transmitting antennas and the receiving antennas 101-1 to 101-3, respectively, A comparison circuit 104 that compares the magnitude of the sum of the powers of the two transfer functions output from the transfer function power detection circuits 111-1 to 111-3 and outputs the comparison result information, and has a multi-input multi-output selection. The circuit 105 outputs two received signals in descending order of the sum of the powers of the two transfer functions based on the output of the comparison circuit 104 among the received signals output from the three receiving circuits 102-1 to 102-3. There is a place to select and output.
[0031]
Next, the operation of the space division multiplexing OFDM receiver of the first embodiment will be described. The space division multiplexed OFDM signals received by the receiving antennas 101-1, 101-2, and 101-3 are respectively received by the receiving circuits 102-1, 102-2, and 102-3 and the received power detecting circuits 103-1 and 103-2. , 103-3. Receiving circuits 102-1, 102-2, and 102-3 respectively perform frequency conversion, automatic gain control (AGC), filtering, and analogy on the input space division multiplexed OFDM signal. NALOG Necessary reception processing such as digital conversion, symbol timing detection and carrier frequency synchronization is performed, and a complex baseband reception signal is output. The complex baseband reception signals output from the reception circuits 102-1, 102-2, and 102-3 are respectively transferred to the transfer function power detection circuits 111-1, 111-2, and 111-3 and the multi-input / multi-output selection circuit 105. Entered.
[0032]
Reception power detection circuits 103-1, 103-2, and 103-3 detect and output the reception power of the input space division multiplexed OFDM signals. The received power output from the received power detection circuits 103-1, 103-2, 103-3 is input to the transfer function power detection circuits 111-1, 111-2, 111-3, respectively. The transfer function power detection circuits 111-1, 111-2, and 111-3 obtain the transfer function power for each transmission antenna using the received reception power and space division multiplexed OFDM signal, respectively, and transfer functions for each reception system Is calculated, and the calculated power sum of the transfer function is output. Since the power of the transfer function is obtained for each reception system by the number of transmission antennas by using a predetermined preamble signal, the sum of the power of the transfer function of the number of transmission antennas is calculated for each reception system.
[0033]
Since the power of the transfer function for each transmit antenna is the power when a signal is transmitted independently from each transmit antenna, the sum of the power of the transfer function for each receive system is when the signal is transmitted independently from each transmit antenna Is equal to the sum of the powers. The sum of the power of the transfer function for each reception system output from the transfer function power detection circuits 111-1, 111-2, and 111-3 is input to the comparison circuit 104. The comparison circuit 104 compares the magnitude of the sum of the powers of the input transfer functions for each reception system, and outputs comparison result information.
[0034]
The comparison result information output from the comparison circuit 104 is input to the multi-input / multi-output selection circuit 105. Based on the comparison result information input from the comparison circuit 104, the multi-input / multi-output selection circuit 105 transfers transfer functions from the three complex baseband reception signals input from the reception circuits 102-1, 102-2, and 102-3. Selects and outputs two complex baseband received signals having a large sum of powers.
[0035]
The two complex baseband received signals output from the multi-input multi-output selection circuit 105 are input to Fourier transform circuits 106-1 and 106-2, respectively. The Fourier transform circuits 106-1 and 106-2 perform processing such as guard interval removal on the input complex baseband received signals, respectively, perform Fourier transform, and output a space division multiplexed subcarrier signal.
[0036]
The spatial division multiplexed subcarrier signals output from Fourier transform circuits 106-1 and 106-2 are input to channel estimation circuits 107-1 and 107-2 and spatial division multiplexed signal separation circuit 108, respectively. Channel estimation circuits 107-1 and 107-2 estimate the transfer function representing the state of the propagation path (channel) for each transmission antenna for each subcarrier using the respective spatial division multiplexed subcarrier signals, and are estimated. The transfer function of each subcarrier is output. Due to fading, each signal between each transmitting antenna and each receiving antenna receives a different amplitude / phase variation (transfer function), but a known reference signal for channel estimation is transmitted and prepared on the receiving side. By comparing with a known ideal signal, the transfer function of each channel can be estimated.
[0037]
The transfer functions of the subcarriers output from the channel estimation circuits 107-1 and 107-2 are input to the space division multiplex signal separation circuit 108, respectively. The spatial division multiplex signal demultiplexing circuit 108 has a transfer function of each subcarrier input from the channel estimation circuits 107-1 and 107-2 and a space division multiplex subcarrier signal input from the Fourier transform circuits 106-1 and 106-2. Are used to estimate the subcarrier modulation signals transmitted from the two transmission antennas, respectively, and output two subcarrier modulation signals.
[0038]
The two subcarrier modulation signals output from the space division multiplex signal separation circuit 108 are input to the parallel-serial conversion circuit 109. The parallel-serial conversion circuit 109 performs parallel-serial conversion on the two input parallel subcarrier modulation signals and outputs the result. The subcarrier modulation signal output from the parallel / serial conversion circuit 109 is input to the subcarrier demodulation circuit 110. The subcarrier demodulation circuit 110 demodulates the input subcarrier modulation signal and outputs a bit string obtained as a result of the demodulation.
[0039]
In general, when performing selective diversity reception, a reception sequence that improves the SNR of a received signal is selected. In a communication system that does not perform space division multiplexing communication, the SNR of the received signal can be improved with high accuracy by selecting a receiving system having a high power level of the received signal.
[0040]
However, in the conventional space division multiplexing OFDM receiver described above, signals are received in a state in which transmission signals from a plurality of transmission antennas are superimposed on a radio propagation path, so that when each transmission signal is received alone Even when the received signal power is at a high level, the received power of the spatial division multiplexed signal in the preamble signal part for detecting power may be reduced by canceling each other's signals due to the phase shift when the transmitted signal is superimposed. is there. On the contrary, when the transmission signals are superimposed on each other in phase, reception signal power higher than when each transmission signal is received alone may be detected.
[0041]
Therefore, when the reception system is selected based on the reception power of the space division multiplexed OFDM signal, it does not reflect the reception power in a state where the space division multiplexed OFDM signal is separated into a plurality of transmission signals. There was a problem that the gain was insufficient.
[0042]
According to the space division multiplexing OFDM receiver of the first embodiment, the criterion for selecting a reception system by selective diversity reception is based on the sum of the powers of the transfer functions of the transmission antennas for each reception system. In a certain reception system, the power of the transfer function with each transmission antenna represents the reception power when a signal is transmitted independently from each transmission antenna.
[0043]
Therefore, the power of the transfer function reflects the received power in a state where the space division multiplexed OFDM signal is separated into OFDM signals transmitted from the respective transmission antennas. That is, by selecting a receiving system based on the received power in a state where the space division multiplexed OFDM signal is separated into OFDM signals transmitted from the respective transmitting antennas, the gain of selection diversity is improved, and the SNR of the received signal is increased. The reception system to be improved is selected, and the error rate characteristics of the space division multiplexing OFDM receiver can be improved.
[0044]
(Second embodiment)
A space division multiplexing OFDM receiver according to the second embodiment will be described with reference to FIGS. FIG. 2 is a block diagram of a transfer function power detection circuit according to the second embodiment (corresponding to claim 2). FIG. 5 is a diagram illustrating an example of a preamble signal used for power estimation of a transfer function in the second embodiment. This figure assumes a case where there are two transmission antennas and three reception antennas, and two received signals are selected from three received signals and demodulated. In the present embodiment, an example of the internal configuration of the transfer function power detection circuit 111-1 of the first embodiment described above is applied to the example of FIG.
[0045]
As shown in FIG. 2, the transfer function power detection circuit 111-1 of the second embodiment includes a delay circuit 201 that delays a reception signal output from the reception circuit 102-1 for a predetermined time, and a reception circuit 102-1. Between the reception signal output from the delay circuit 201 and the delay signal output from the delay circuit 201, and the difference between the reception signal output from the reception circuit 102-1 and the delay signal output from the delay circuit 201 Subtracting circuit 203 that calculates the output of addition circuit 202, square circuit 204-1 that squares the output of addition circuit 202, square circuit 204-2 that squares the output of subtraction circuit 203, and the output of squaring circuit 204-1 is a predetermined value. Average circuit 205-1 that averages over the number of samples, average circuit 205-2 that averages the output of squaring circuit 204-2 over a predetermined number of samples, and the output and average of average circuit 205-1 It includes an adder 206 for adding the output of the road 205-2, and a multiplier circuit 207 for multiplying the received power outputted from the reception power detection circuit 103-1 to the output of the adder circuit 206.
[0046]
Next, the operation of the transfer function power detection circuit of the second embodiment will be described. The present embodiment corresponds to the space division multiplexing OFDM system for transmitting the preamble shown in FIG. The preamble in FIG. 5 is composed of two types of basic elements, Short preamble and Long preamble. Short preamble is used for reception power detection, symbol timing synchronization, and carrier frequency synchronization. Long preamble is used for carrier frequency synchronization, transfer function power detection, and channel estimation. Long preambles A-1, A-2, and A-3 are the same signal pattern. A-4 is a signal pattern obtained by multiplying Long preamble by -1. The transfer function power detection circuits 111-2 and 111-3 have the same internal configuration.
[0047]
The complex baseband reception signal output from the reception circuit 102-1 is input to the delay circuit 210 and also input to the addition circuit 202 and the subtraction circuit 203. The delay circuit 201 delays the input complex baseband reception signal by the length of the Long preamble length and outputs it. The delay signal output from the delay circuit 201 is input to the addition circuit 202 and the subtraction circuit 203.
[0048]
The adder circuit 202 adds the input complex baseband received signal and the delayed signal, and outputs the result to the square circuit 204-1. By this addition, the transfer function component of the transmission antenna 2 is canceled, and only the transfer function component of the transmission antenna 1 remains. The subtraction circuit 203 subtracts the delay signal from the input complex baseband reception signal and outputs the result to the square circuit 204-2. By this subtraction, the transfer function component of the transmission antenna 1 is canceled, and the transfer function component of the transmission antenna 2 remains. Here, it is assumed that a long preamble signal composed of K (positive integer) samples is L (k) (k = 1, 2,..., K). The transfer function matrix between the transmitting antenna 1 and the receiving antenna 1 is represented by h ₁₁ , The transfer function matrix between the transmitting antenna 2 and the receiving antenna 1 is represented by h _{twenty one} And The superposed signals of A-1 and A-3 received by the receiving antenna 1 are (h ₁₁ + H _{twenty one} ) The received signal with L (k), A-2 and A-4 superimposed is (h ₁₁ -H _{twenty one} ) L (k). The power normalized by AGC in the receiving circuit 102-1 is G ₁ Since the received signal output from the receiving circuit 102-1 is normalized by the power of the spatial division multiplexing OFDM signal by AGC, (h ₁₁ + H _{twenty one} ) L (k) / G ₁ , (H ₁₁ -H _{twenty one} ) L (k) / G ₁ It is expressed. As can be seen from FIG. 5, the superimposed signals (h) of the A-2 and A-4 portions ₁₁ -H _{twenty one} ) L (k) / G ₁ Is a superimposed signal (h) of the A-1 and A-3 portions. ₁₁ + H _{twenty one} ) L (k) / G ₁ Since the delay is longer by the longer preamble length, the delay circuit 201 (h ₁₁ + H _{twenty one} ) L (k) / G ₁ Is delayed by the length of the long preamble length, then (h ₁₁ -H _{twenty one} ) L (k) / G ₁ And (h ₁₁ + H _{twenty one} ) L (k) / G ₁ Is input to the adder circuit 212. The output of the adder circuit 202 is (h ₁₁ + H _{twenty one} ) L (k) / G ₁ + (H ₁₁ -H _{twenty one} ) L (k) / G ₁ = 2h ₁₁ L (k) / G ₁ It becomes. From this result, the output signal of the adder circuit 202 is the transfer function component h of the transmission antenna 2. _{twenty one} Is canceled and the transfer function component h of the transmitting antenna 1 is ₁₁ It can be seen that remains. By the same calculation, the output of the subtraction circuit 203 is (h ₁₁ + H _{twenty one} ) L (k) / G ₁ -(H ₁₁ -H _{twenty one} ) L (k) / G ₁ = 2h _{twenty one} L (k) / G ₁ Thus, the output of the subtraction circuit 203 is the transfer function component h of the transmission antenna 1. ₁₁ Is canceled and the transfer function component h of the transmitting antenna 2 is _{twenty one} It can be seen that remains.
[0049]
The square circuits 204-1 and 204-2 calculate the power value by calculating the square of the input complex signal. The power values output from the square circuits 204-1 and 204-2 are input to the averaging circuits 205-1 and 205-2, respectively. Average circuits 205-1 and 205-2 calculate the average values of the input power values over the long preamble length, and output them to adder circuit 206.
[0050]
The output of the average circuit 205-1 is the power value of the transfer function with the transmission antenna 1, and the output of the average circuit 205-2 is the power value of the transfer function with the transmission antenna 2. Adder circuit 206 adds the input signals from averaging circuits 205-1 and 205-2 and outputs the result to multiplication circuit 207. The output signal of the adder circuit 206 calculates the sum of the power of the transfer function with each transmitting antenna in the receiving system. However, since automatic gain control (AGC) is performed in the receiving circuit 102-1, the output signal of the adding circuit 206 is normalized by the received power of the space division multiplexed signal. Therefore, the multiplication circuit 207 multiplies the reception power output from the reception power detection circuit 103-1 by the output of the addition circuit 206, thereby calculating the sum of the power of the transfer function with each transmission antenna. . An output signal of the multiplication circuit 207 is output to the comparison circuit 104.
[0051]
(Third embodiment)
A space division multiplexing OFDM receiver according to the third embodiment will be described with reference to FIGS. 3 and 6. FIG. FIG. 3 is a block diagram of a transfer function power detection circuit according to the third embodiment (corresponding to claim 3). FIG. 6 is a diagram illustrating an example of a preamble signal used for power estimation of a transfer function in the third embodiment. This figure assumes a case where there are two transmission antennas and three reception antennas, and two received signals are selected from three received signals and demodulated. In the present embodiment, an example of the internal configuration of the transfer function power detection circuit 111-1 of the first embodiment described above is applied to the example of FIG.
[0052]
As shown in FIG. 3, the transfer function power detection circuit 111-1 of the third embodiment has a square circuit 301 that squares the reception signal output from the reception circuit 102-1 and outputs the output of the square circuit 301 to a predetermined value. An average circuit 302 that averages over the number of samples, a delay circuit 303 that delays the output of the average circuit 302 for a predetermined time, an adder circuit 304 that adds the output of the delay circuit 303 and the output of the average circuit 302, and A multiplication circuit 305 that multiplies the output of the addition circuit 304 by the reception power output from the reception power detection circuit 103-1.
[0053]
Next, the operation of the transfer function power detection circuit of the third embodiment will be described. This embodiment corresponds to the space division multiplexing OFDM system for transmitting the preamble shown in FIG. The preamble in FIG. 6 is composed of two types of basic elements, Short preamble and Long preamble. Short preamble is used for reception power detection, symbol timing synchronization, and carrier frequency synchronization. Long preamble is used for carrier frequency synchronization, transfer function power detection, and channel estimation. Long preambles B-1 and B-2 have the same signal pattern. When long preamble B-1 is transmitted from transmission antenna 1, transmission antenna 2 does not transmit a signal, and transmission antenna 2 transmits a long preamble B-. The transmitting antenna 1 is not transmitting a signal when 2 is transmitted. The transfer function power detection circuits 111-2 and 111-3 have the same internal configuration.
[0054]
The complex baseband reception signal output from the reception circuit 102-1 is input to the square circuit 301. The square circuit 301 calculates and outputs a power value by squaring the input complex baseband received signal. The power value output from the square circuit 301 is input to the averaging circuit 302. The averaging circuit 302 averages the input power value over the long preamble length. Here, the average value of the power of Long preamble B-1 is the power of the transfer function of transmitting antenna 1. Moreover, the average value of the power of Long preamble B-2 is the power of the transfer function of the transmitting antenna 2.
[0055]
The output of the averaging circuit 302 is input to the delay circuit 303 and the adding circuit 304. The delay circuit 303 delays the input signal by the time of the Long preamble length, and outputs it to the adder circuit 304. The adder circuit 304 adds the delay signal input from the delay circuit 303 and the signal input from the averaging circuit 302 and outputs the result to the multiplier circuit 305.
[0056]
The output signal of the adder circuit 304 calculates the sum of the power of the transfer function of each transmitting antenna in the receiving system. However, since automatic gain control (AGC) is performed in the receiving circuit 102-1, the output signal of the adding circuit 304 is normalized by the received power of the space division multiplexed signal. Therefore, the multiplication circuit 305 multiplies the reception power output from the reception power detection circuit 103-1 by the output of the addition circuit 304, thereby calculating the sum of the powers of the transfer functions of the transmission antennas. An output signal of the multiplication circuit 305 is output to the comparison circuit 104.
[0057]
(Fourth embodiment)
A space division multiplexing OFDM receiver according to the fourth embodiment will be described with reference to FIG. FIG. 4 is a block diagram of the space division multiplexing OFDM receiver of the fourth embodiment (corresponding to claim 4). The figure assumes a case where there are two transmission antennas and three reception antennas, and two received signals are selected from three received signals and demodulated.
[0058]
In the space division multiplexing OFDM receiver of the fourth embodiment, as shown in FIG. 4, two different OFDM signal sequences simultaneously transmitted from two transmitting antennas using the same frequency are superimposed on the radio propagation path. Three reception circuits 402-1 to 402-3 that receive the space division multiplexing OFDM signals and perform reception processing, and three reception power detection circuits that receive the space division multiplexing OFDM signals and detect their reception power 403-1 to 403 and the preamble signal portion added to the head of the packet of the reception signal output by the three reception circuits 402-1 to 402-3 are the received three systems of received signals, Fourier transform circuits 406-1 to 406-1, respectively. 3 and the data signal portion following the preamble signal portion is selected based on the output of the comparison circuit 404 from two received signals of the three received signals. Output switching circuit 405 that outputs to Fourier transform circuits 406-1 and 2, and three Fourier transform circuits 406-1 to 406-3 sub-receive the received signals output from output switching circuit 405 using Fourier transform, respectively. Each carrier is divided into space-division multiplexed signals for each carrier, a predetermined space-division multiplexed subcarrier signal is output, and each of the subcarriers is output using two systems of space-division multiplexed subcarrier signals output from the multi-input multi-output selection circuit 412 Two channel estimation circuits 407-1 and 40-2 for estimating a transfer function for each of the transmission antennas, and two channel estimation circuits for the spatial division multiplexed subcarrier signals output by the Fourier transform circuits 406-1 and 40-2. Using the transfer function estimation result of each subcarrier output from 407-1 and 407-1, each of the two transmit antennas is used. A spatial division multiplexing signal separation circuit 408 that separates the transmitted subcarrier modulation signals into two subcarrier modulation signals; and a subcarrier demodulation circuit 410 that demodulates the subcarrier modulation signals output from the spatial division multiplexing signal separation circuit 408. This is a spatial division multiplexing OFDM receiver.
[0059]
Here, the feature of the fourth embodiment is that each of the spatial division multiplexed subcarrier signals output from the three Fourier transform circuits 406-1 to 406-3 and the three received power detection circuits 403-1 to 403-3. A subcarrier power calculation circuit 411 that calculates the sum of received power of all subcarrier signals in all combinations when two received signals are selected from three received signals using the received power output from The comparison circuit 404 compares the outputs of the subcarrier power calculation circuit 411 and outputs the combination information of the two systems of received signals that maximizes the sum of the received power of all the subcarrier signals, and the multi-input multi-output selection circuit 412 Is based on the combination information of the two received signals output from the comparison circuit 404, and the three empty channels output from the three Fourier transform circuits 406-1 to 406-3. Select MIMO sub-carrier signals of the two systems from division multiplexed subcarrier signal is at the output.
[0060]
Next, the operation of the space division multiplexing OFDM receiver of the fourth embodiment will be described. The spatial division multiplexed OFDM signals received by the receiving antennas 401-1, 401-2, and 401-3 are respectively received by the receiving circuits 402-1, 402-2, and 402-3 and the received power detection circuits 403-1 and 403-2. , 403-3. Receiving circuits 402-1, 402-2, and 402-3 respectively perform frequency conversion, automatic gain control (AGC), filtering, analog-digital conversion, symbol timing detection, and carrier frequency synchronization on the input space division multiplexed OFDM signal. And the like, and a complex baseband received signal is output. The complex baseband reception signals output from the reception circuits 402-1, 402-2, and 402-3 are input to the output switching circuit 405.
[0061]
On the other hand, the reception power detection circuits 403-1, 403-2, and 403-3 detect and output the reception power of the input space division multiplexed OFDM signals. The received power output from the received power detection circuits 403-1, 403-2, and 403-3 is input to the subcarrier power calculation circuit 411.
[0062]
The output switching circuit 405 converts the preamble signal portions added to the packet heads of the three complex baseband received signals input from the receiving circuits 402-1, 402-2, and 402-3, respectively, into the Fourier transform circuit 406-1, Based on the comparison result information input from the comparison circuit 404 to the data signal portion that is output to 406-2 and 406-3 and follows the preamble signal portion, input from the reception circuits 402-1, 402-2, and 402-3. Of the three complex baseband received signals, the two complex baseband received signals that maximize the sum of the received power of the subcarrier signals are selected and output. The three preamble signal parts output from the output switching circuit 405 are subjected to Fourier transform in Fourier transform circuits 406-1, 406-2, and 406-3, and then used for each subcarrier power calculation and channel estimation of each subcarrier. It is output to the subcarrier power calculation circuit 411 and the multi-input multi-output selection circuit 412 as a space division multiplexed subcarrier signal to be used.
[0063]
On the other hand, the data signal portions of the two complex baseband received signals output from the output switching circuit 405 are converted into space division multiplexed subcarrier signals by Fourier transform in Fourier transform circuits 406-1 and 406-2, respectively. It is output to the division multiplexed signal separation circuit 408.
[0064]
The subcarrier power calculation circuit 411 is input from the space division multiplexed subcarrier signal input from the Fourier transform circuits 406-1, 406-2, and 406-3 and the received power detection circuits 403-1, 403-2, and 403-3. In all combinations of selecting two received signals from three received signals using the received received power, a plurality of transfer functions of each subcarrier are estimated, and a spatial division multiplexed subcarrier signal is obtained from the estimated transfer function. The reception power of each subcarrier in a state separated into two subcarrier modulation signals is calculated, and the sum of the reception powers of all subcarriers is output.
[0065]
Here, since there are three combinations for selecting the two received signals from the three received signals, the sum of the received powers of all three subcarriers is output. The sum of received power of all subcarriers output from the subcarrier power calculation circuit 411 is input to the comparison circuit 404. The comparison circuit 404 compares the sum of the received powers of all three subcarriers of the input three patterns, and outputs the information of the combination of the two received signals with the largest sum of the received powers of all the subcarriers. And output to the multi-input multi-output selection circuit 412.
[0066]
The multi-input multi-output selection circuit 412 is input from the Fourier transform circuits 406-1, 406-2, and 406-3 based on the combination information of the two systems of received signals that are comparison result information input from the comparison circuit 404. Two systems are selected from the system space division multiplexed subcarrier signals and output to channel estimation circuits 407-1 and 407-2. Channel estimation circuits 407-1 and 407-2 estimate the transfer function representing the state of the propagation path (channel) for each transmission antenna for each subcarrier using the respective spatial division multiplexed subcarrier signals. Output the transfer function of the subcarrier.
[0067]
Due to fading, each signal between each transmitting antenna and each receiving antenna receives a different amplitude / phase variation (transfer function), but a known reference signal for channel estimation is transmitted and prepared on the receiving side. By comparing with a known ideal signal, the transfer function of each channel can be estimated. The subcarrier transfer functions output from channel estimation circuits 407-1 and 407-2 are input to space division multiplexed signal separation circuit 408, respectively.
[0068]
The space division multiplex signal separation circuit 408 receives the subcarrier transfer function input from the channel estimation circuits 407-1 and 407-2 and the space division multiplex subcarrier signal input from the Fourier transform circuits 406-1 and 406-2. The subcarrier modulation signals transmitted from the two transmission antennas are estimated and output.
[0069]
The two subcarrier modulation signals output from the spatial division multiplexing signal separation circuit 408 are input to the parallel-serial conversion circuit 409. The parallel-serial conversion circuit 409 performs parallel-serial conversion on the two input parallel subcarrier modulation signals and outputs them. The subcarrier modulation signal output from the parallel / serial conversion circuit 409 is input to the subcarrier demodulation circuit 410. The subcarrier demodulation circuit 410 demodulates the input subcarrier modulation signal and outputs a bit string obtained as a result of the demodulation.
[0070]
According to the spatial division multiplexing OFDM receiver of the fourth embodiment, the criterion for selecting a reception system in selective diversity reception is the sum of the received powers of all subcarriers after separation of the spatial division multiplexing subcarrier signals. Based on size. Each space division multiplexed subcarrier signal is demodulated after separating the space division multiplexed subcarrier signal into subcarrier modulation signals transmitted from the respective transmission antennas. The combination of two received signals that maximizes the sum of the received powers of all subcarriers of the subcarrier modulation signal is a combination that improves the SNR in the subcarrier modulation signal. That is, by selecting a combination of receiving systems that maximizes the sum of received powers of modulated signals of all subcarriers, the gain of selection diversity is improved, and the SNR of the subcarrier modulated signal after space division multiplexing subcarrier signal separation is improved. Is selected, and the error rate characteristic of the space division multiplexing OFDM receiver can be improved.
[0071]
【The invention's effect】
As described above, according to the present invention, when selective diversity reception is applied to the space division multiplexing OFDM system, the reception signal is selected by selecting the reception system using the power of the transfer function between the transmission and reception antennas. Since it is possible to select a receiving system that increases the SNR, it is possible to improve the gain of selection diversity and improve the error rate characteristics of the space division multiplexing OFDM receiver.
[Brief description of the drawings]
FIG. 1 is a block diagram of a space division multiplexing OFDM receiver according to a first embodiment.
FIG. 2 is a block diagram of a transfer function power detection circuit according to a second embodiment.
FIG. 3 is a block diagram of a transfer function power detection circuit according to a third embodiment.
FIG. 4 is a block diagram of a space division multiplexing OFDM receiver according to a fourth embodiment.
FIG. 5 is a diagram showing an example of a preamble signal used for power estimation of a transfer function in the second embodiment.
FIG. 6 is a diagram illustrating an example of a preamble signal used for power estimation of a transfer function in the third embodiment.
FIG. 7 is a block diagram of a conventional space division multiplexing OFDM receiver.
[Explanation of symbols]
1-1 to 1-3, 101-1 to 101-3, 401-1 to 401-3 Receiving antenna
2-1 to 2-3, 102-1 to 102-3, 402-1 to 402-3 receiving circuit
3-1 to 3-3, 103-1 to 103-3, 403-1 to 403-3 Received power detection circuit
4, 104, 404 Comparison circuit
5, 105, 412 Multiple input multiple output selection circuit
6-1, 6-2, 106-1, 106-2, 406-1 to 406-3 Fourier transform circuit
7-1, 7-2, 107-1, 107-2, 407-1, 407-2 Channel estimation circuit
8, 108, 408 Spatial division multiplexing signal separation circuit
9, 109, 409 Parallel to serial converter
10, 110, 410 Subcarrier demodulation circuit
111-1 to 111-3 transfer function power detection circuit
201, 303 delay circuit
202, 206, 304 Adder circuit
203 Subtraction circuit
204-1, 204-2, 301 square circuit
205-1, 205-2, 302 Average circuit
207, 305 multiplication circuit
405 Output switching circuit
411 Subcarrier power calculation circuit
A-1 to A-3, B-1, B-2 Long preamble
A-4 Long preamble * -1

Claims (4)

Respectively receives spatial division multiplexed OFDM signals in which L (different Orthogonal Frequency Division Multiplexing) signal sequences transmitted from L transmission antennas using the same frequency at the same time are superimposed on a radio channel. M (M> 0: integer) reception means for performing reception processing,
M received power detection means for respectively receiving the space division multiplexed OFDM signals and detecting the received power;
The N (0 <N <M: integer) received signals output from the first multi-input multi-output selecting means are subjected to Fourier transform to be separated into space division multiplexed signals for each subcarrier, and predetermined space division N Fourier transform means for outputting multiple subcarrier signals;
N channel estimation means for estimating a transfer function for each transmission antenna of each subcarrier using each spatially demultiplexed subcarrier signal output by the N Fourier transform means;
The spatial division multiplexed subcarrier signals output from the N Fourier transform units are transmitted from the L transmission antennas using the transfer function estimation results of the subcarriers output from the N channel estimation units, respectively. Space division multiplexed signal separation means for separating the L subcarrier modulation signals,
In a space division multiplexing OFDM receiver comprising subcarrier demodulation means for demodulating the subcarrier modulation signal output from the space division multiplexing signal separation means,
Sum of powers of L transfer functions between the L transmission antennas and the respective reception antennas based on reception signals output from the M reception units and reception power output from the M reception power detection units M transfer function power detection means for calculating
First comparison means for comparing the magnitude of the sum of powers of L transfer functions respectively output from the M transfer function power detection means and outputting the comparison result information;
The first multi-input / multi-output selection means is an order in which the sum of the powers of the L transfer functions is large based on the output of the first comparison means among the reception signals output from the M reception means. And a means for selecting and outputting N (N <M: integer) received signals for output. The transfer function power detection means includes
First delay means for delaying a reception signal output from the reception means for a predetermined time;
First addition means for adding the reception signal output from the reception means and the delay signal output from the first delay means;
First subtraction means for calculating a difference between a reception signal output from the reception means and a delay signal output from the first delay means;
First square means for squaring the output of the first addition means;
Second square means for squaring the output of the first subtraction means;
First averaging means for averaging the output of the first square means over a predetermined number of samples;
Second averaging means for averaging the output of the second square means over a predetermined number of samples;
Second addition means for adding the output of the first averaging means and the output of the second averaging means;
2. The space division multiplexing OFDM receiver according to claim 1, further comprising a first multiplying unit that multiplies the output of the second adding unit by the received power output from the received power detecting unit. The transfer function power detection means includes
Third square means for squaring the reception signal output from the reception means;
A third averaging means for averaging the output of the third square means over a predetermined number of samples;
Second delay means for delaying the output of the third averaging means for a predetermined time;
A third adding means for adding the output of the second delay means and the output of the third averaging means;
2. The space division multiplexing OFDM receiver according to claim 1, further comprising: a second multiplying unit that multiplies the output of the third adding unit and the received power output from the received power detecting unit. Receiving processing is performed by receiving spatial division multiplexed OFDM signals in which L different OFDM signal sequences simultaneously transmitted from the L (L> 0: integer) transmission antennas using the same frequency are superimposed on the radio propagation path. M (M> 0: integer) receiving means;
M received power detection means for respectively receiving the space division multiplexed OFDM signals and detecting the received power;
The preamble signal part added to the head of the packet of the reception signal output from the M reception means outputs the input M-system reception signals to the first to Mth Fourier transform means, respectively, and continues to the preamble signal part. The data signal portion selects N (N <M: integer) received signals from the input M received signals based on the output of the second comparing means and outputs the selected signals to the first to Nth Fourier transform means. Output switching means,
The M number of Fourier transform means separates the received signal output from the output switching means into space division multiplexed signals for each subcarrier using Fourier transform, and outputs a predetermined space division multiplexed subcarrier signal. With
N channel estimation means for estimating a transfer function for each transmission antenna of each subcarrier using N systems of space division multiplexed subcarrier signals output from the second multiple-input multiple-output selection means;
The L transmit antennas are obtained by using the transfer function estimation results of the subcarriers output from the N channel estimators for the spatial division multiplexed subcarrier signals output from the first to Nth Fourier transform means. A space division multiplex signal separation means for separating the signal into L subcarrier modulation signals respectively transmitted from
In a space division multiplexing OFDM receiver comprising subcarrier demodulation means for demodulating the subcarrier modulation signal output from the space division multiplexing signal separation means,
N received signals are selected from M received signals by using the respective spatial division multiplexed subcarrier signals output from the M Fourier transform means and the received power output from the M received power detecting means. Subcarrier power calculation means for calculating the sum of received power of all subcarrier signals in all combinations of cases,
The second comparing means includes means for comparing the outputs of the subcarrier power calculating means and outputting combination information of N systems of received signals that maximizes the sum of received power of all subcarrier signals,
The second multi-input / multi-output selection means is configured to perform M space division multiplexing of M systems output from the M Fourier transform means, based on combination information of N systems of received signals output from the second comparison means. A space division OFDM receiver comprising means for selecting and outputting N types of space division multiplexed subcarrier signals from subcarrier signals.

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