The present invention relates to a transmission apparatus, a reception apparatus, and a communication system.
In a digital communication system, frequency selectivity and time variability in a transmission line arise because of multipath phasing caused by a transmission signal being reflected by buildings or the like or Doppler variation caused by the terminal moving. In such a multipath environment, a received signal becomes a signal in which a transmission symbol and a symbol arriving after a delay time interfere with each other.
With this kind of transmission line having frequency selectivity, a single carrier block transmission method has recently attracted attention in order to acquire the best receiving characteristics (see, for example, Non Patent Literature 1 listed below). The single carrier (SC) block transmission system can reduce the peak power compared with an OFDM (Orthogonal Frequency Division Multiplexing) transmission method, which is multi-carrier (Multiple Carrier: MC) block transmission (see, for example, Non Patent Literature 2 listed below).
With a transmitter that performs SC block transmission, measures against multipath phasing are taken by performing, for example, the following kinds of transmission. First, after generating a PSK (Phase Shift Keying) signal or a QAM (Quadrature Amplitude Modulation) signal, which are digital modulation signals, in a “Modulator”, the digital modulation signal is converted to a time domain signal by a precoder and an IDFT (Inverse Discrete Fourier Transform) processing unit. Thereafter, as a measure against multipath phasing, a CP (Cyclic Prefix) is inserted by a CP insertion unit. The CP insertion unit copies a predetermined number of samples behind the time domain signal and adds the samples to the head of a transmission signal. In addition to this method, as a measure against multipath phasing, ZP (Zero Padding: zero insertion) is performed by inserting zero into a start portion and an end portion of data.
Furthermore, in order to suppress transmission peak power, in a transmitter that performs SC transmission, a precoder normally performs DFT (Discrete Fourier Transform) processing.
According to the conventional SC block transmission technique described above, transmission peak power is suppressed while the effect of multipath phasing is reduced. However, with the SC block transmission, the phase and the amplitude become discontinuous between the SC blocks, and thus out-of-band spectrum or out-of-band leakage occurs. Because the out-of-band spectrum interferes with an adjacent channel, the out-of-band spectrum needs to be suppressed. Further, in a general communication system, a spectral mask is defined, and the out-of-band spectrum needs to be suppressed so as to satisfy the mask.
The present invention has been achieved in view of the above problems, and an object of the present invention is to provide a transmission apparatus, a reception apparatus, and a communication system that can suppress an out-of-band spectrum.
In order to solve the above problems and achieve the object, an aspect of the present invention is a transmission apparatus that transmits a block signal including a plurality of data symbols, the transmission apparatus including: a data-symbol generation unit that generates data symbols; a symbol arrangement unit that arranges the data symbol and same-quadrant symbols such that two or more same-quadrant symbols that become signal points in a same quadrant in a complex plane are inserted at predetermined positions in a block signal to generate a block symbol; an interpolation unit that performs interpolation processing on the block symbol; and a CP insertion unit that inserts a Cyclic Prefix into a signal on which the interpolation processing has been performed to generate the block signal.
The transmission apparatus according to the present invention has an effect that an out-of-band spectrum can be suppressed.
Exemplary embodiments of a transmission apparatus, a reception apparatus, and a communication system according to the present invention will be explained below in detail with reference to the accompanying drawings. The present invention is not limited to the embodiments.
The data-symbol generation unit 1 generates data symbols (for example, a PSK (Phase Shift Keying) symbol and a QAM (Quadrature Amplitude Modulation) symbol). The fixed-symbol arrangement unit 2 arranges a preassigned fixed symbol at a predetermined position between data symbols to generate a block symbol (symbols for one block consisting of data symbols and fixed symbols). The interpolation unit 3 converts the data symbols after arrangement of the fixed symbol to a frequency domain signal once and then converts the frequency domain signal again to a time domain signal. The CP insertion unit 4 inserts a CP into the time domain signal converted by the interpolation unit 3. The CP-inserted signal is transmitted as an SC block signal (block signal). It is assumed that one block signal consists of N symbols and one frame consists of NF block symbols.
Conventional SC block transmission is described here. In the SC block transmission, the phase and the amplitude become discontinuous between SC blocks.
An operation according to the present embodiment is described next. It is assumed that CP insertion is performed for each block and one block consists of N (N is an integer equal to or larger than 1) data symbols. In this case, if it is assumed that the number of fixed symbols to be arranged in one block (per N data symbols) is x, the data-symbol generation unit 1 outputs (N−x) data symbols for each block.
The fixed-symbol arrangement unit 2 generates a fixed symbol A and inserts the fixed symbol A at a predetermined position between data symbols.
The interpolation unit 3 performs oversampling (processing to increase the sampling rate, that is, to reduce the sampling interval) by using a signal interpolation formula described, for example, in “B. Porat, “A Course in Digital Signal Processing”, John Wiley and Sons Inc., 1997” (hereinafter, “Porat Literature”). Oversampling is performed such that sampling points per symbol becomes L with respect to the time domain signal input to the interpolation unit 3. That is, oversampling is performed such that the sampling rate becomes L times with respect to input. The oversampling rate is a value indicating how many times the sampling rate after oversampling is larger than the input sampling rate.
Specifically, for example, the interpolation unit 3 converts the input time domain signal to a frequency domain signal, performs zero insertion processing for inserting zero with respect to the frequency domain signal, and converts the frequency domain signal to the time domain signal again. In this manner, oversampling can be performed by using the zero insertion processing. Oversampling (interpolation processing) in the interpolation unit 3 can be performed by using other interpolation methods. A method of performing interpolation (oversampling) without changing the input time domain signal to the frequency domain signal once can be used.
The number of samples of the time domain signal output from the interpolation unit 3 becomes N·L, and the number of samples of the signal after CP insertion becomes (N+NCP)·L.
The DFT unit 3-1 performs N-point DFT processing to convert the input time domain signal to a frequency domain signal. The waveform shaping filter 3-2 performs filtering processing to remove a signal other than signals in a desired frequency domain on the frequency domain signal. In the filtering processing, processing such as Nyquist filtering described in, for example, “T. S. Rappaport, “Wireless Communications”, 2nd edition, Prentice Hall PTR, 2002” can be used. The filtering processing is not limited thereto.
The oversampling/IDFT unit 3-3 increases the number of samples by zero insertion or the like with respect to the frequency domain signal having been subjected to the filtering processing (increases the number of samples to the number corresponding to the oversampling rate L), and thereafter, generates a time domain signal by performing the IDFT processing on the frequency domain signal. Instead of the oversampling/IDFT unit 3-3, an oversampling unit that performs oversampling and an IDFT unit that performs IDFT processing can be provided. Because the N-point DFT processing and L·N point IDFT processing are performed by using IFFT (Inverse Fast Fourier Transform) and FFT that require a low computation amount, it is desired that N is 2P (P is an integer equal to or larger than 1) and L is an integer.
Thereafter, the CP insertion unit 4 inserts the CP in the time domain to generate an SC block signal. When the waveform shaping filter 3-2 does not change the number of samples of the signal, the number of samples of the signal after CP insertion becomes (N+NCP)·L as in the configuration example illustrated in
In the configuration example illustrated in
From the specific example in
To improve the continuity of the phase and amplitude between blocks, phase rotation and amplitude adjustment can be applied to the fixed symbol in a block. Further, as the operation of the oversampling/IDFT unit 3-3, not only the operation example illustrated in
In the example illustrated in
d=[d0,d1,d2,d3,d4,d5]T (1)
s=[s0,s2,s3,s4,s5]T (2)
s′=[0,s0,s1,s2,s3,s4,S5,0]T (3)
When s′ represented by the equation (3) is input to the IDFT unit (the oversampling/IDFT unit 3-3), the output of the IDFT unit becomes as represented by the following equation (4), and the first and fifth signals become d0 and d3 with ck (phase rotation and amplitude) being added by the DFT and IDFT processing.
y=[c0d0,y1,y2,y3,c4d3,y5,y6,y7]T (4)
In this case, if d0=f·c0−1, d3=f·c4−1, and the CP length is set to NCP=4, then the head of the block symbol and the head of the CP become fixed symbols f. Generally, in the example illustrated in
In the example illustrated in
As described above, according to the present embodiment, a fixed symbol is inserted at a fixed position between data blocks and interpolation is performed on the data after insertion of the fixed symbol such that the phase and amplitude do not become discontinuous between the last sample of each block and the first sample of each block after CP insertion. Thus, the continuity of the phase and amplitude between blocks can be maintained; therefore, the out-of-band spectrum can be suppressed.
In the SC block transmission, a pilot signal is used in some cases for estimation of a transmission line and synchronous processing, and in the frequency domain, pilot signals and DFT-processed data symbols are arranged. In the present embodiment, an example in which pilot signals are arranged in the frequency domain is described.
The pilot-signal generation unit 6 outputs a pilot signal as a frequency domain signal and the time domain signal of the pilot signal. The pilot signal as the frequency domain signal is input to the waveform shaping filter 3-21 and used for multiplexing. The pilot signal as the time domain signal including the waveform shaping processing in the time domain is input to the fixed-symbol arrangement unit 2-2 and used for calculating a fixed symbol.
The data-symbol generation unit 1-1 generates data symbols as in the data-symbol generation unit 1 according to the first embodiment. The number of data symbols to be generated per block is N−x−NP (NP is the number of pilot symbols per block).
The fixed-symbol arrangement unit 2-2 generates a fixed symbol on the basis of the pilot signals (pilot symbols) as the time domain signal and arranges the fixed symbol at a predetermined position between data symbols. The DFT unit 3-1 performs DFT processing on the symbols output from the fixed-symbol arrangement unit 2-2 to convert the symbols to a frequency domain signal, and inputs the frequency domain signal to the waveform shaping filter 3-20. The waveform shaping filter 3-20 performs waveform shaping in the frequency domain on the input from the DFT unit 3-1 and outputs the processed signal to the frequency-domain arrangement unit 5. Further, the waveform shaping filter 3-21 performs waveform shaping on the pilot signals as the frequency domain signal and outputs the processed signal to the frequency-domain arrangement unit 5.
The frequency-domain arrangement unit 5 arranges, in the frequency domain, the data symbols and the fixed symbol in the frequency domain output from the waveform shaping filter 3-20 and the pilot signals in the frequency domain output from the waveform shaping filter 3-21, and outputs them to the oversampling/IDFT unit 3-3.
The oversampling/IDFT unit 3-3 performs oversampling and IDFT processing on the signal output from the frequency-domain arrangement unit 5 as in the first embodiment and outputs the signal to the CP insertion unit 4. The CP insertion unit 4 performs CP insertion processing on the input signal as in the first embodiment.
As a specific example, it is assumed that the total number of symbols in one block is N, the number of symbols of the pilot signal in one block is NP=N/2, and the number of data symbols (including fixed symbols) in one block is N/2.
In the example illustrated in
A specific example is described below. To simplify the description, it is assumed that the number of pilot symbols is NT=N/2 and the number of data symbols is ND=N/2. If it is assumed that the pilot symbol arranged in the frequency domain is represented by the following equation (5) and a DFT matrix is represented by the following equation (6), the pilot symbol in the time domain becomes as represented by the following equation (7).
If it is assumed that the DFT-processed data signal, which is arranged in the frequency domain, is represented by the following equation (8), the time domain signal becomes as represented by the following equation (9). Further, t1 indicated by the following equation (10) is a vector indicating ND data symbols. The following equation (11) is also established.
The pilot signal and the DFT-processed data signal multiplexed in the frequency domain become as represented by the following equation (12), and the time domain signal becomes as represented by the following equation (13).
r=pz+sz (12)
y=WNHr=WNH(pz+sz)=t+q (13)
In the time domain, when it is desired to set the fixed signal “A” as y1=yN−NCP+1=A in symbol times n=1 and n=N−NCP+1, it suffices that symbols as represented by the following equations (14) and (15) are inserted into the data symbols.
t1,1=A1′=√{square root over (2)}·A−√{square root over (2)}·q1,1 (14)
t1,N/2−N
Furthermore, if it is assumed that ek′ is a constant and gk′ is a coefficient depending on other data symbols, a fixed-symbol calculation method in which other data is taken into consideration such as Ak′=ck′A−bk′qk′+ek′gk′ can be used. A specific example is described below. If it is assumed that K=N/NT, the position of the pilot signal in the block signal is IT={K, 2K, 3K, . . . , NTK}, and the DFT-processed data symbol is present in other places.
The data symbol and the pilot symbol in the time domain are respectively represented by the following equations (16) and (17).
yD=WNHPDWN
yT=WNHPTp (17)
If it is assumed that ID and IT are respectively positions of the DFT-processed data symbol and the pilot symbol in the frequency domain, in the above equations, the arrangement matrix becomes as represented by the following equations (18) and (19).
When it is desired to set the K=1th and k=(N−NCP+1)th symbols of the output signal as “A”, the pilot signal and an interference wave need to be considered. To simplify signage, in the case of the following equation (20), if it is desired to set the K=1th data symbol as “A”, for example, the first data symbol is set as represented by the following equation (21), assuming that [v]m is the m-th element of a vector v.
A=WNHPDWN
d1=A−[yT]1 (21)
If it is assumed that [A]m,n is the (m, n)th element of a matrix A, when it is desired to set the k=(N−NCP+1)th symbol as “A”, the n-th signal at an arbitrary position is obtained by solving the following equation (22).
As a result, by setting the value as represented by the following equation (23), the k=(N−NCP+1)th symbol becomes “A”.
In the above example, it is assumed that ND+NT=N. However, in the case of ND+NT<N, it suffices that a fixed signal that takes the time domain pilot signal into consideration is input by using the same designing method as in the first embodiment.
It is assumed that the pilot symbol and the DFT-processed data symbol in the frequency domain are represented by the following equation (24) and the DFT-processed signal is represented by the following equation (25) in the case where ND=NT. If it is assumed that 0N is a vector established by N zeroes, the arrangement of the pilot signal and the data symbol in the frequency domain become as represented by the following equations (26) and (27).
d=[d0,d1, . . . ,dN
s=[s0,s1, . . . ,sN
pz=[0(N−N
sz=[0(N−N
The time domain signal becomes as represented by the following equation (28), and the pilot symbol in the time domain becomes as represented by the following equation (29). The pilot signal and the DFT-processed data signal multiplexed in the frequency domain become as represented by the following equation (30), and the time domain signal becomes as represented by the following equation (31).
t=[tsT,tsT]T=WNHsz (28)
q=[qsT,−qsT]T=WNHpz (29)
r=pz+sz (30)
y=WNHr=WNH(pz+sz)=t+q (31)
In the example illustrated in
In the time domain, when it is desired to set the fixed symbol “A” as y1=tkx+1=A in symbol times n=1 and n=kx+1, it suffices that the following symbols are inserted into the data symbols. If it is assumed that ky≧ND, the first data symbol and the (ky+1−ND)th data symbol are set as represented by the following equations (32) and (33). Complex numbers c1 and b1 depend on the values of N, ND, and NT, and the processing in the IDFT unit 3-3. If NCP=N−kx, it is possible to design such that the head of the CP becomes the fixed symbol.
d1=A1′=c1A−b1q1 (32)
dky−N
In the present embodiment, because the pilot signal are inserted, the value of the fixed symbol Ak′ changes according to the insertion positions of the pilot signal and the fixed symbol. Therefore, the processing described above is performed for each block. However, if the insertion positions of the pilot signal and the fixed symbol are fixed between the blocks, it is possible to obtain Ak′ once and thereafter use Ak′ that is already obtained.
An example of not including the pilot signal has been described in the first embodiment, and an example of including the pilot signal has been described in the present embodiment. However, the configuration can be such that a block including the pilot signal and a block not including the pilot signal are mixed. Even if these blocks are mixed, if it is set such that the fixed symbol is arranged at the same position in the time domain, discontinuity of the phase and amplitude between blocks can be prevented in a similar manner; therefore, an effect of suppressing the out-of-band spectrum can be acquired.
In the present embodiment, an example of multiplexing the pilot signals in the frequency domain has been described. However, the pilot signals can be multiplexed in the time domain.
As described above, according to the present embodiment, when the pilot signal is multiplexed and transmitted, the fixed-symbol arrangement unit 2-2 calculates the fixed symbol such that the fixed symbol multiplexed with the pilot signal has a predetermined value at a predetermined position, on the basis of the arrangement position of the pilot signal. Accordingly, even if the pilot signal is multiplexed, the continuity of the phase and amplitude between blocks can be maintained; therefore, the out-of-band spectrum can be suppressed.
In the first and second embodiments, an example in which a fixed symbol is arranged at a predetermined position has been described. In the present embodiment, a symbol that becomes a signal point in the same quadrant (hereinafter, “same-quadrant symbol”) is arranged instead of the fixed symbol in a complex plane (an IQ plane).
The data-symbol generation unit 1-2 generates N data symbols per block. However, x symbols to be used as the same-quadrant symbols among the N data symbols are assigned with data having the number of bits less than that of normal data symbols (corresponding to low-order data bits described later). The data-symbol generation unit 1-2 generates the same-quadrant symbols by performing mapping such that the same-quadrant symbols of the N data symbols are in the same quadrant. The same-quadrant mapping unit 9 arranges the same-quadrant symbols at predetermined positions in a similar manner to the fixed symbols of the first embodiment to generate a block symbol (symbols for one block consisting of data symbols and same-quadrant symbols). Mapping of the same-quadrant symbols (generation of the same-quadrant symbols) can be performed by the same-quadrant mapping unit 9 by acquiring data bits from the data-symbol generation unit 1-2.
As the quadrant range becomes smaller, the out-of-band spectrum decreases. Therefore, A(i) and B(i) can be mapped not in any of the four quadrants, but in a narrower predetermined range.
The fixed symbol in the first embodiment is one of the same-quadrant symbols and can be considered as an example in which the above predetermined range is narrowed such that only one signal point is included in a predetermined range.
In the above example, two symbols are the same-quadrant symbols in a block; however, three or more symbols can be set as the same-quadrant symbols. Further, phase rotation and amplitude adjustment can be performed on A(i) and B(i) so that the out-of-band spectrum decreases.
As described above, according to the present embodiment, symbols within the same quadrant or a certain range (symbols in which a part of bit values of all the bits of the symbol is set to a fixed value) are used instead of the fixed symbol, to perform interpolation as in the first embodiment. Thus, the continuity of the phase and amplitude between blocks can be maintained; therefore, the out-of-band spectrum can be suppressed and data loss can be reduced.
The reception apparatus according to the present embodiment is such that a synchronization unit 12 performs synchronous processing such as frame synchronization, frequency synchronization, and symbol synchronization on a received signal (an SC block signal). A CP removal unit 13 performs CP removal on the received signal after the synchronous processing. A DFT unit 14 performs DFT processing on the CP-removed received signal. A transmission-line estimation unit 16 performs estimation of a transmission line in accordance with the DFT-processed signal. A sampling unit 15 performs downsampling on the DFT-processed signal. An FDE unit (equalization unit) 17 performs FDE (Frequency Domain Equalizer: frequency domain equalization) processing on the basis of the downsampled signal and the estimation result of the transmission line. An IDFT unit 18 performs IDFT processing on the FDE-processed signal. A fixed-symbol removal unit 19 removes a fixed symbol from the IDFT-processed signal. A demodulation/decoding unit 20 performs demodulation and decoding processing on the signal after the fixed symbol has been removed.
When the first symbol of a block is set as a fixed signal, the length of the CP increases by one symbol by using the first fixed symbol of the next block; therefore, the characteristics with respect to multipath phasing improve. Therefore, the CP removal unit 13 can use one additional symbol as the CP to remove the CP portion.
As described above, in the present embodiment, the reception apparatus that receives the SC block signal transmitted by the transmission apparatus described in the first and second embodiments has been described. The reception apparatus performs demodulation and decoding on the received signal after downsampling and removal of the fixed symbol have been performed. Accordingly, it is possible to perform demodulation and decoding processing on the signal that is transmitted after the fixed symbol is inserted thereinto and interpolation processing is performed thereon.
The reception apparatus according to the present embodiment is similar to the reception apparatus according to the fourth embodiment, except that a demodulation/decoding/same quadrant demapping unit (demodulation/decoding unit) 19-1 is included instead of the fixed-symbol removal unit 19 and the demodulation/decoding unit 20. Constituent elements having functions identical to those of the fourth embodiment are denoted by like reference signs in the fourth embodiment, and redundant explanations thereof will be omitted.
The demodulation/decoding/same quadrant demapping unit 19-1 removes fixed bits from the same-quadrant symbols in accordance with the signal after the IDFT processing has been performed by the IDFT unit 18, and handles the remaining bits after removal of the fixed bits as data bits to perform the decoding processing. The data symbols other than the same-quadrant symbols are subjected to the demodulation and decoding processing as in the fourth embodiment.
As described above, in the present embodiment, the reception apparatus that receives the SC block signal transmitted from the transmission apparatus described in the third embodiment has been described. The reception apparatus performs downsampling, removes the fixed bits from the same-quadrant symbols, and handles the remaining bits after removal of the fixed bits as data bits to perform the demodulation and decoding processing. Accordingly, the signal transmitted from the transmission apparatus described in the third embodiment can be demodulated and decoded.
In the embodiments described above, an example of performing SC transmission has been described; however, the present invention is not limited thereto, and can be applied to a transmission apparatus and a reception apparatus of various systems including a wired system. Further, the present invention has been described by using DFT and IDFT processing; however, the present invention is not limited thereto, and FFT (Fast Fourier Transform) and IFFT (Inverse FFT) can be used, and a plurality of methods can be combined. The configurations of the transmission apparatus and the reception apparatus are not limited to the apparatus configurations described in the respective embodiments.
Furthermore, an example of inserting the CP as a guard interval has been described in the embodiments described above; however, a guard interval other than the CP can be used. Also in this case, it suffices that the head data symbol and the head of the guard interval are arranged as fixed symbols (or the same-quadrant symbols).
A transmission apparatus according to a sixth embodiment is described next. In the first embodiment, an example of using a plurality of types of fixed symbols has been described. In the present embodiment, as an expansion thereof, a method of arranging fixed symbols for suppressing the out-of-band spectrum is described.
To obtain the spectrum suppression effect, the same fixed symbol series is used in all the blocks, and the same fixed symbols are arranged at the same positions between the blocks. The method of arranging the fixed symbol series is as described below. F0 of the fixed symbol series is arranged at the first position and the XCPth ((N−XCP+1)th position from the head) position from the end in the block. With reference to these positions, the fixed symbols are arranged on the right and left of the reference position in the order of [F−NL, F−NL+1, F−NL+2, . . . , F—1, F0, F1, . . . , FNR] such that the relative sequence of the fixed symbol series is not changed.
For example, as illustrated in
It is assumed here that XCP is a sufficiently larger value than NL+NR+1 so that the fixed symbols [F−NL, F−NL+1, F−NL+2, . . . , F−1] behind the CP portion of the data and the fixed symbols [F0, F1, . . . , FNR] arranged from the (N−XCP+1)th position do not overlap with each other. For example, all the fixed symbols can be set to zero like Fi=0.
After zero insertion, as illustrated in
Furthermore, in the present embodiment, the fixed symbol series becomes the same between the blocks. However, the present embodiment can be configured such that the fixed symbol series becomes the same-quadrant symbol as described in the third embodiment. As a specific example, the symbol arrangement example in
As described above, according to the present embodiment, with reference to the positions of the first symbol and the head of a portion to be copied in the CP insertion of the block symbol, the same fixed symbol series is arranged in each block before and after the reference position. Accordingly, the continuity of the phase and amplitude between blocks can be maintained; therefore, the out-of-band spectrum can be suppressed.
As described above, the transmission apparatus, the reception apparatus, and the communication system according to the present invention are useful in a communication system that performs SC block transmission, and are particularly suitable for a communication system that performs CP insertion.
1, 1-1, 1-2 data-symbol generation unit, 2, 2-2 fixed-symbol arrangement unit, 3 interpolation unit, 3-1 DFT unit, 3-2, 3-20, 3-21 waveform shaping filter, 3-3 oversampling/IDFT unit, 3-4 zero insertion unit, 3-5 IDFT unit, 4 CP insertion unit, 5 frequency-domain arrangement unit, 6 pilot-signal generation unit, 7 frequency/time domain conversion unit, 8 time-domain multiplexing unit, 9 same-quadrant mapping unit, 12 synchronization unit, 13 CP removal unit, 14 DFT unit, 15 sampling unit, 16 transmission-line estimation unit, 17 FDE unit, 18 IDFT unit, 19 fixed-symbol removal unit, 19-1 demodulation/decoding/same quadrant demapping unit, 20 demodulation/decoding unit.
Number | Date | Country | Kind |
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2013-041963 | Mar 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2014/055311 | 3/3/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/136726 | 9/12/2014 | WO | A |
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