JP4887385B2 - Wireless communication apparatus and wireless communication method - Google Patents

Description

  The present invention relates to a wireless communication apparatus and a wireless communication method, and more particularly to a wireless communication apparatus and a wireless communication method that combine OFDM and CDMA.

  In recent years, a system combining OFDM (Orthogonal Frequency Division Multiple) and CDMA has been studied as a method for transmitting a large amount of data at high speed. In a system combining OFDM and CDMA, there are a system in which chips in which data is spread are arranged on subcarriers in the frequency direction and a system in which chips are arranged on subcarriers in the time direction.

  When spreading in the frequency direction, frequency diversity fading due to frequency selective fading due to the multipath environment, so the frequency diversity effect at the time of despreading is obtained, but the orthogonality between spreading codes is lost, Reception characteristics deteriorate.

  When spread in the time axis direction, the propagation path fluctuation in the time axis direction is relatively gentle compared to the frequency direction, so a frequency diversity effect cannot be obtained, but orthogonality between spreading codes is maintained. It is. However, since the data allocated to subcarriers with a strong drop has a very small received SNR, there is a high possibility of complete error.

  In particular, when code multiplexing is performed using multi-level modulation such as 16QAM, the reception performance is greatly deteriorated due to the loss of orthogonality between spreading codes. Therefore, spreading in the time axis direction has better characteristics than spreading in the frequency direction. .

  However, the conventional apparatuses have both advantages and disadvantages, and there is a problem that it is difficult to increase transmission efficiency by combining OFDM and CDMA.

  The present invention has been made in view of this point, and an object thereof is to provide a wireless communication apparatus and a wireless communication method capable of performing communication with good transmission efficiency by combining OFDM and CDMA.

  The wireless communication apparatus according to the first aspect of the present invention uses spreading means for multiplying transmission data by spreading code and spreading, and a chip in which transmission data requiring orthogonality between spreading codes is spread as a subcarrier. Mapping means for arranging chips arranged in the time axis direction and in which transmission data in which transmission data requiring no reception quality is spread is arranged on a subcarrier in the frequency direction or two dimensions in the frequency direction and the time axis direction, and the mapping means And a transmission means for transmitting the chip arranged in each subcarrier.

  According to this configuration, in OFDM-CDMA communication, a chip in which data is spread is arranged in the time direction or according to the orthogonality of a spreading code required for data to be transmitted and the quality of a received signal, or the quality of a received signal. By arranging the subcarriers in the frequency direction, communication with good transmission efficiency can be performed.

  The wireless communication apparatus according to the second aspect of the present invention comprises: a determination unit that compares, on a subcarrier basis, whether the estimated propagation path environment is equal to or higher than a predetermined level. The mapping unit spreads transmission data. The chips are arranged in the time axis direction on subcarriers having a better propagation path environment than a predetermined level, and the chips in which transmission data are spread are placed in the frequency direction or frequency direction on subcarriers having a propagation path environment worse than the predetermined level. A configuration in which two-dimensional arrangement in the time axis direction is employed.

  According to this configuration, in OFDM-CDMA communication, the arrangement of chips in which transmission data is spread is arranged in the time axis direction on subcarriers having a better propagation path environment than a predetermined level, and the propagation path environment is improved from a predetermined level. By arranging the bad subcarriers in the frequency direction, both the effect of maintaining orthogonality between spreading codes when chips are spread in the time direction and the frequency diversity effect when chips are spread in the frequency direction can be obtained simultaneously. Can do.

  A wireless communication apparatus according to a third aspect of the present invention includes encoding means for encoding transmission data to make information bits and parity bits as transmission data itself, and spreading means includes the information bits and the parity bits. And the mapping means arranges the chip in which the information bits and the parity bit are spread in the time axis direction on the subcarrier, and the chip in which the information bits are spread on the subcarrier in the frequency direction. Or the structure arrange | positioned in two dimensions of a frequency direction and a time-axis direction is taken.

  According to this configuration, in OFDM-CDMA communication, chips in which information bits are spread are arranged on subcarriers in two dimensions in the frequency direction and in the time direction, and chips in which parity bits are spread are arranged on subcarriers in the time direction. Thus, it is possible to prevent the level of information bits from being extremely lowered and to maintain the orthogonality of the parity bits, so that the characteristics of each bit necessary for error correction can be utilized.

  The wireless communication apparatus according to the fourth aspect of the present invention comprises encoding means for encoding transmission data of different transmission data at different coding rates, and the spreading means applies a spreading code to the encoded transmission data. Multiplying and spreading, the mapping means arranges transmission data encoded at a coding rate lower than a predetermined coding rate on the subcarrier in the time axis direction, and codes at a coding rate higher than the predetermined coding rate. The transmission data is arranged in the frequency direction or two-dimensionally in the frequency direction and the time axis direction on the subcarrier.

  According to this configuration, when transmitting data encoded at a plurality of different encoding rates, for data encoded at a high encoding rate, the chip in which the data is spread is two-dimensionally in the frequency direction and the time direction. For data coded at a low coding rate and placed on subcarriers, the quality of reception is extremely high for data coded at a high coding rate by placing chips on which data is spread on the subcarriers in the time direction. It is possible to prevent occurrence of bad bits and to prevent a state where a small number of parity bits are not received correctly and error correction is not performed correctly.

  In the radio communication apparatus according to the fifth aspect of the present invention, the spreading means includes a first spreading means for spreading the transmission data at a predetermined spreading factor, and a first spreading means for spreading the transmission data at a higher spreading factor than the first spreading means. 2, spreading means, wherein the mapping means arranges the transmission data spread by the first spreading means in the time axis direction on the subcarrier, and sets the transmission data spread by the second spreading means on the frequency of the subcarrier. A configuration is adopted in which two directions are arranged in the direction or frequency direction and the time axis direction.

  A radio communication apparatus according to a sixth aspect of the present invention includes a first modulation unit that modulates transmission data by a predetermined modulation scheme, and a modulation having a high multi-level number of information that can be transmitted by one symbol from the first modulation unit. Second mapping means for modulating transmission data in a system, and mapping means arranges the transmission data modulated by the first modulation means in a frequency direction or two-dimensionally in the frequency direction and the time axis direction on subcarriers. The transmission data modulated by the second modulation means is arranged on the subcarrier in the time axis direction.

  The radio communication apparatus according to the seventh aspect of the present invention rearranges reception means for receiving signals transmitted using a plurality of subcarriers, and chips arranged in the time axis direction on the subcarriers into one data. De-mapping means for rearranging chips arranged in the frequency direction or two-dimensionally in the frequency direction and the time axis direction into one data, and de-spreading means for de-spreading the data rearranged by the demapping means The structure which comprises these is taken.

  According to these configurations, in OFDM-CDMA communication, a chip in which data is spread is placed in the time direction according to the propagation state of subcarriers or the orthogonality of spreading codes required for data to be transmitted and the quality of received signals. Alternatively, communication with good transmission efficiency can be performed by arranging the subcarriers in the frequency direction.

  A wireless communication apparatus according to an eighth aspect of the present invention comprises a determination unit that compares, on a subcarrier basis, whether the estimated propagation path environment is equal to or higher than a predetermined level, and the demapping unit includes: The chips arranged in the time axis direction in the subcarriers having a better propagation path environment than the predetermined level are rearranged into one data, and the chips in which the transmission data is spread are changed to the propagation path environment from the predetermined level. A configuration is adopted in which chips arranged in two dimensions in the frequency direction or in the frequency direction and the time axis direction are rearranged into one data in a bad subcarrier.

  According to this configuration, in OFDM-CDMA communication, the arrangement of chips in which transmission data is spread is arranged in the time axis direction on subcarriers having a better propagation path environment than a predetermined level, and the propagation path environment is improved from a predetermined level. By arranging the bad subcarriers in the frequency direction, both the effect of maintaining orthogonality between spreading codes when chips are spread in the time direction and the frequency diversity effect when chips are spread in the frequency direction can be obtained simultaneously. Can do.

  A wireless communication apparatus according to a ninth aspect of the present invention comprises decoding means for decoding data from information bits and parity bits of data, and the demapping means includes a chip in which parity bits are spread in a subcarrier. A configuration is adopted in which the chips are rearranged in the time axis direction, and the chips in which the information bits are spread are rearranged in the frequency direction or two dimensions in the frequency direction and the time axis direction.

  According to this configuration, in OFDM-CDMA communication, chips in which information bits are spread are arranged on subcarriers in two dimensions in the frequency direction and in the time direction, and chips in which parity bits are spread are arranged on subcarriers in the time direction. Thus, it is possible to prevent the level of information bits from being extremely lowered and to maintain the orthogonality of the parity bits, so that the characteristics of each bit necessary for error correction can be utilized.

  The wireless communication apparatus according to the tenth aspect of the present invention comprises decoding means for decoding data obtained by encoding different transmission data at different coding rates, and the demapping means includes the first encoding For the first data encoded at the rate, the chips in which the first data is spread are rearranged in the time axis direction in the subcarrier, and the first data encoded at a higher encoding rate than the first encoding rate For the two data, a configuration is adopted in which the chips in which the second data is spread are rearranged in the frequency direction or two-dimensionally in the frequency direction and the time axis direction.

  According to this configuration, when transmitting data encoded at a plurality of different encoding rates, for data encoded at a high encoding rate, the chip in which the data is spread is two-dimensionally in the frequency direction and the time direction. For data coded at a low coding rate and placed on subcarriers, the quality of reception is extremely high for data coded at a high coding rate by placing chips on which data is spread on the subcarriers in the time direction. It is possible to prevent occurrence of bad bits and to prevent a state where a small number of parity bits are not received correctly and error correction is not performed correctly.

  In the wireless communication apparatus according to the eleventh aspect of the present invention, the despreading means receives a first despreading means for despreading the received data at a predetermined spreading factor, and receives at a higher spreading factor than the first despreading means. Second despreading means for despreading the processed data, and the demapping means rearranges the chips arranged in the time axis direction on the subcarriers and outputs them to the first despreading means, and outputs the frequency to the subcarriers. The chips arranged in two dimensions in the direction or frequency direction and the time axis direction are rearranged and output to the second despreading means, and the first despreading means converts the chips arranged in the time axis direction to the subcarriers. The rearranged data is despread, and the second despreading unit despreads the data obtained by rearranging the chips arranged in the frequency direction or two-dimensionally in the frequency direction and the time axis direction on the subcarrier.

  The wireless communication apparatus according to the twelfth aspect of the present invention has a first demodulating means for demodulating received data by a predetermined modulation method, and a multi-value number of information that can be transmitted by one symbol from the first demodulating means is high. A second modulation means for demodulating data received by the modulation method, wherein the demapping means rearranges the chips arranged in two dimensions in the frequency direction or in the frequency direction and the time axis direction on the subcarriers. Output to the demodulating means, rearrange the chips arranged in the time axis direction on the subcarriers and output to the second demodulating means, and the first demodulating means outputs the subcarriers in the frequency direction or the frequency direction and the time axis direction. The second demodulating means demodulates the data obtained by rearranging the chips arranged in the time axis direction on the subcarrier, and demodulates the data obtained by rearranging the two-dimensionally arranged chips. That.

  A base station apparatus according to a thirteenth aspect of the present invention employs a configuration including the above wireless communication apparatus. A communication terminal apparatus according to the fourteenth aspect of the present invention employs a configuration comprising the above wireless communication apparatus.

  According to these configurations, in OFDM-CDMA communication, a chip in which data is spread is placed in the time direction according to the propagation state of subcarriers or the orthogonality of spreading codes required for data to be transmitted and the quality of received signals. Alternatively, communication with good transmission efficiency can be performed by arranging the subcarriers in the frequency direction.

  In the radio communication method according to the fifteenth aspect of the present invention, on the transmission side, transmission data is spread, and chips in which transmission data for which orthogonality between spreading codes is required are spread are arranged on a subcarrier in the time axis direction. In addition, a chip in which transmission data for which reception quality without a drop is required is spread is arranged on a subcarrier in the frequency direction or two dimensions in the frequency direction and the time axis direction, and a signal in which the chip is arranged on each subcarrier is arranged. Transmit and receive a signal transmitted using a plurality of subcarriers on the receiving side, rearrange the chips arranged in the time axis direction on the subcarriers into one data, and set the frequency direction or frequency direction to the subcarriers. Chips arranged in two dimensions in the time axis direction were rearranged into one data, and the rearranged data was despread.

  According to this method, in OFDM-CDMA communication, a chip in which data is spread is placed in the time direction or in accordance with the propagation path condition of subcarriers or the orthogonality of spreading codes required for data to be transmitted and the quality of received signals. By arranging the subcarriers in the frequency direction, communication with good transmission efficiency can be performed.

  According to the present invention, communication with good transmission efficiency can be performed in OFDM-CDMA communication.

  When a chip in which transmission data is spread is arranged and transmitted on subcarriers in the frequency direction, the orthogonality between spreading codes is lost due to variations in the level of chips arranged on each subcarrier due to frequency selective fading.

  Further, when a chip in which transmission data is spread is arranged in the time direction and transmitted from each subcarrier, transmission data transmitted by a subcarrier having a poor propagation path environment has a very small SNR at the time of reception.

  The present inventor has focused on the fact that the fluctuation in the time axis direction is more gradual than the fluctuation in the frequency axis, and has reached the present invention.

  In the present invention, in OFDM-CDMA communication, a chip in which data is spread is set in a time direction or a frequency direction according to the propagation path condition of subcarriers or the orthogonality of spreading codes required for data to be transmitted and the quality of received signals. In the subcarrier.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
(Embodiment 1)
FIG. 1 is a block diagram showing a configuration of a radio communication apparatus according to Embodiment 1 of the present invention. 1 includes an encoder 101, a modulator 102, a spreader 103, a wireless reception unit 104, a determination unit 105, a mapping unit 106, an IFFT unit 107, and a P / S conversion. Instrument 108; The I adding unit 109 and the wireless transmission unit 110 are mainly configured.

  In FIG. 1, an encoder 101 encodes data to be transmitted and outputs the encoded data to the modulator 102. The modulator 102 modulates the data and outputs it to the spreader 103. Spreader 103 multiplies the data by a spreading code and outputs the result to mapping section 106.

  The radio reception unit 104 receives a radio signal transmitted from a communication partner, performs amplification, conversion to a baseband frequency, demodulation, and decoding, and obtains information on the propagation path condition of each subcarrier. Radio receiving section 104 then outputs information on the propagation path condition to determination section 105. The determining unit 105 determines for each subcarrier whether the propagation path state is equal to or higher than a predetermined level, and outputs the determination result to the mapping unit 106.

  The mapping unit 106 arranges chips on which data is diffused in the time axis direction. In addition, mapping section 106 arranges chips in which data is spread in the frequency direction on subcarriers whose propagation path conditions are less than a predetermined level. Then, mapping section 106 outputs the data (chip) arranged on each subcarrier to IFFT section 107.

  IFFT section 107 performs inverse fast Fourier transform on the data arranged on each subcarrier, and outputs the converted data to P / S converter 108. The P / S converter 108 performs parallel-serial conversion on the data after IFFT. The data is output to the I adding unit 109.

  G. The I adding unit 109 adds a guard interval to the data and outputs the data to the wireless transmission unit 110. The wireless transmission unit 110 converts data into a wireless frequency and transmits the data.

  Next, the data arrangement operation of the wireless communication apparatus according to the present embodiment will be described. FIG. 2 is a diagram illustrating an example of channel fluctuation in the frequency direction. In FIG. 2, the vertical axis represents the reception level, and the horizontal axis represents the frequency. F1 to f12 indicate subcarrier frequencies. In FIG. 2, the reception levels of the signals f2, f5, f8, and f11 are very low due to frequency selective fading. The level difference for each frequency is very large. For example, the level difference between the f10 signal and the f11 signal, or the level difference between the f11 signal and the f12 signal is very large.

  On the other hand, the change in the time direction at each frequency has a smaller level difference than the change in the frequency direction. FIG. 3 is a diagram illustrating an example of channel fluctuation on the time axis. In FIG. 3, the vertical axis indicates the reception level, and the horizontal axis indicates time. The reception level in FIG. 3 and the reception level in FIG. 2 are represented on the same scale.

  FIG. 3 shows time-direction fluctuations of the signals of the frequencies f10, f11, and f12 in FIG. It can be seen that the level difference of each signal in the time direction is smaller than that in FIG.

  Therefore, the present invention transmits a chip in which data is spread by arranging it in a time direction on a carrier whose reception level is equal to or higher than a predetermined level and transmits the chip in which data is spread to a carrier whose reception level is lower than a predetermined level. Transmit in the frequency direction.

  FIG. 4 is a diagram illustrating an example of a chip arrangement of the wireless communication apparatus according to the present embodiment. In FIG. 4, the vertical axis represents time, and the horizontal axis represents frequency. Further, the frequencies f1 to f12 in FIG. 4 correspond to the frequencies f1 to f12 in FIG.

  The radio communication apparatus 100 arranges the chips in which data is spread on the subcarriers of the frequencies f1, f3, f4, f6, f7, f9, f10, and f12 whose reception level is equal to or higher than a predetermined level in the time direction. For example, chips obtained by spreading certain transmission data are arranged at positions 411, 412, 413, and 414.

  Radio communication apparatus 100 then arranges the chip in which the data is spread in the frequency direction on subcarriers of frequencies f2, f5, f8, and f11 whose reception level is less than a predetermined level. For example, chips obtained by diffusing certain transmission data are arranged at positions 421, 431, 441, and 451, respectively.

  Next, details of the mapping unit 106 will be described. FIG. 5 is a block diagram illustrating an example of the configuration of the mapping unit of the wireless communication apparatus according to the present embodiment. The mapping unit 106 in FIG. 5 mainly includes a mapping controller 501, a switch 502, a time direction mapping unit 503, a frequency direction mapping unit 504, and a switch 505.

  In FIG. 5, the mapping controller 501 controls the switch 502 and the switch 505 based on the determination result output from the determination unit 105.

  The mapping controller 501 issues an instruction to output, from the spreader 103 to the time direction mapping unit 503, data in which the chip first output from the time direction mapping unit 503 is placed on a subcarrier whose propagation path condition is a predetermined level or higher. Output to the switch 502. Next, mapping controller 501 outputs to switch 502 an instruction to output data to be allocated to subcarriers whose propagation path conditions are below a predetermined level from spreader 103 to frequency direction mapping section 504.

  Also, the mapping controller 501 outputs the number of subcarriers whose channel state is equal to or higher than a predetermined level to the time direction mapping unit 503, and the number of subcarriers whose chip is below the predetermined level. Is output to the frequency direction mapping unit 504. The mapping controller 501 also outputs to the switch 505 the frequency of subcarriers whose propagation path conditions are greater than or equal to a predetermined level and the frequency of subcarriers whose propagation path conditions are less than a predetermined level.

  The switch 502 outputs the chip spread in the spreader 103 to the time direction mapping unit 503 or the frequency direction mapping unit 504 in accordance with an instruction from the mapping controller 501. The time direction mapping unit 503 arranges chips on each subcarrier in the time direction and outputs the chips to the switch 505. The frequency direction mapping unit 504 arranges chips on each subcarrier in the frequency direction and outputs the chips to the switch 505.

  The switch 505 outputs the chip output from the time direction mapping unit 503 to a subcarrier whose propagation path state is equal to or higher than a predetermined level, and the chip output from the frequency direction mapping unit 504 has a propagation path state lower than a predetermined level. Is output to the subcarrier.

  Hereinafter, an example of mapping using the above configuration will be described. FIG. 6 is a diagram illustrating an example of data after spreading. FIG. 7 is a diagram illustrating an example in which data is arranged on subcarriers. Each of the data in FIG. 6 has a spreading factor of 4, and one data is spread on four chips. Further, in FIG. 7, carrier frequencies f1, f3, f6, and f7 have propagation path conditions above a predetermined level, and carrier frequencies f2, f4, f5, and f8 have propagation path conditions below a predetermined level. is there.

  Data 601 is mapped to frequency f1 in FIG. Next, the data 602 is mapped in the time axis direction to the frequency f3 in FIG. 7, the data 603 to the frequency f6 in FIG. 7, and the data 604 to the frequency f7 in FIG.

  After data is mapped in the time axis direction to a carrier frequency where the propagation path condition is above a predetermined level, the data is mapped in the frequency direction to a carrier frequency where the propagation path condition is below a predetermined level.

  Data 605 is mapped to positions 701, 702, 703, and 704 at frequencies f2, f4, f5, and f8. Similarly, data 606, 607, and 608 are mapped to frequencies f2, f4, f5, and f8 in units of chips.

  With the above operation, radio communication apparatus 100 maps data in a time axis direction to a carrier frequency whose propagation path condition is equal to or higher than a predetermined level, and transmits data to a carrier frequency whose propagation path condition is lower than a predetermined level in the frequency direction. Map with.

  Next, an example of receiving data transmitted by the wireless communication device 100 will be described. FIG. 8 is a block diagram showing a configuration of the wireless communication apparatus according to Embodiment 1 of the present invention. A wireless communication device 800 in FIG. I deletion section 802, S / P converter 803, FFT section 804, demapping section 805, channel estimation section 806, determination section 807, radio transmission section 808, despreader 809, demodulator 810 and a decoder 811 are mainly configured.

  In FIG. 8, the wireless reception unit 801 receives a wireless signal transmitted from the wireless communication apparatus 100, converts the wireless signal into a baseband frequency, and converts the obtained reception signal into a G.D. The data is output to the I deletion unit 802. G. The I deletion unit 802 removes the guard interval from the received signal and outputs it to the S / P converter 803.

  The S / P converter 803 performs serial-parallel conversion of the data and outputs it to the FFT unit 804. The FFT unit 804 performs fast Fourier transform on the received signal and outputs the converted received signal to the demapping unit 805.

  In accordance with the determination result of the determination unit 807, the demapping unit 805 collects chips arranged in the time axis direction as a single data for the received signals of subcarriers whose propagation path state is a predetermined level or higher, and determines the propagation path state. For received signals of subcarriers having a value less than a predetermined level, chips arranged in the frequency direction are collected as one data.

  Then, the demapping unit 805 outputs the rearranged data to the despreader 809. Also, demapping section 805 outputs the received signal of each subcarrier to channel estimation section 806.

  Channel estimation section 806 estimates the propagation path environment for each subcarrier, and outputs the estimation result to determination section 807 and radio transmission section 808. For example, channel estimation section 806 measures the reception quality of pilot signals inserted for each subcarrier, and estimates the propagation path environment for each subcarrier from this reception quality.

  The determination unit 807 determines whether or not the propagation path state is equal to or higher than a predetermined level for each subcarrier, and outputs the determination result to the demapping unit 805. The determination unit 807 performs determination based on the same standard as that of the determination unit 105 of the wireless communication device 100, so that the mapping unit 106 of the wireless communication device 100 and the demapping unit 805 of the wireless communication device 800 perform data chip components in the time direction. And the subcarrier on which the chip component of data is arranged in the frequency direction can be made the same.

  The wireless transmission unit 808 modulates and converts the estimated propagation path state information into a wireless frequency and transmits the wireless signal to the wireless communication apparatus 100 as a wireless signal. Despreader 809 despreads the rearranged received data by multiplying it by a spreading code, and outputs the result to demodulator 810. The demodulator 810 demodulates the received data and outputs it to the decoder 811. The decoder 811 decodes the received data.

  Next, details of the demapping unit 805 will be described. FIG. 9 is a block diagram illustrating an example of the configuration of the demapping unit of the wireless communication apparatus according to the present embodiment. The demapping unit 805 in FIG. 9 mainly includes a demapping controller 901, a switch 902, a time direction demapping unit 903, a frequency direction demapping unit 904, and a switch 905.

  The demapping controller 901 controls the switch 902 and the switch 905 based on the determination result output from the determination unit 807. Further, the demapping controller 901 outputs to the switch 902 the frequency of the subcarrier whose propagation path condition is equal to or higher than a predetermined level and the frequency of the subcarrier whose propagation path condition is lower than a predetermined level.

  The demapping controller 901 outputs, to the time direction demapping unit 903, the number of subcarriers whose channel condition is equal to or higher than a predetermined level, and the chip is the number of subcarriers whose channel condition is lower than a predetermined level. Is output to the frequency direction demapping unit 904.

  The switch 902 outputs a received signal transmitted on a subcarrier whose propagation path condition is equal to or higher than a predetermined level to the time direction demapping unit 903, and received on a subcarrier whose propagation path condition is lower than a predetermined level. The signal is output to the frequency direction demapping unit 904.

  The time direction demapping unit 903 collects chips arranged on each subcarrier in the time direction as one data and outputs the data to the switch 905. The frequency direction demapping unit 904 collects chips arranged on each subcarrier in the frequency direction as one data and outputs the data to the switch 905.

  The switch 905 outputs the reception data output from the time direction demapping unit 903 to the despreader 809, and then outputs the reception data output from the frequency direction demapping unit 904 to the despreader 809.

  As described above, according to the radio communication apparatus of the present embodiment, in OFDM-CDMA communication, the arrangement of chips in which transmission data is spread is arranged in the time axis direction on subcarriers having a better propagation path environment than a predetermined level. If the chip is spread in the time direction by placing it in the frequency direction on a subcarrier whose propagation path environment is worse than a predetermined level, and the effect of maintaining orthogonality between spreading codes when the chip is spread in the time direction Both frequency diversity effects can be obtained simultaneously.

  In the above embodiment, for subcarriers with a poor propagation path environment, the chip in which data is spread is arranged in the frequency direction, but this chip is arranged in two dimensions in the frequency direction and the time axis direction. Also good. Hereinafter, an example in which chips are two-dimensionally arranged will be described.

  FIG. 10 is a block diagram illustrating an example of the configuration of the mapping unit of the wireless communication apparatus according to the present embodiment. 5 identical to those in FIG. 5 are assigned the same reference numerals as in FIG. 5 and detailed descriptions thereof are omitted.

  The mapping unit 106 in FIG. 10 includes a two-dimensional mapping unit 1001 instead of the frequency direction mapping unit 504. The two-dimensional mapping unit 1001 arranges chips in which data is diffused for subcarriers with poor propagation path environment in two dimensions in the frequency direction and the time axis direction and outputs the chips to the switch 505.

  FIG. 11 is a diagram illustrating an example of channel fluctuation in the frequency direction. In FIG. 11, the vertical axis represents the reception level, and the horizontal axis represents the frequency. F1 to f12 indicate subcarrier frequencies. In FIG. 11, the signals f2, f5, f8, f9, f10, and f11 have a very low reception level due to frequency selective fading. For the signals f1, f3, f4, f6, f7, and f12, the reception level is higher than the threshold value 1101.

  FIG. 12 is a diagram illustrating an example of a chip arrangement of the wireless communication apparatus according to the present embodiment. In FIG. 12, the vertical axis represents time and the horizontal axis represents frequency. Further, the frequencies f1 to f12 in FIG. 12 correspond to the frequencies f1 to f12 in FIG.

  The radio communication apparatus 100 arranges the chip in which data is spread on the subcarriers of the frequencies f1, f3, f4, f6, f7, and f12 whose reception level is equal to or higher than a predetermined level in the time direction. For example, chips obtained by diffusing certain transmission data are arranged at positions 1211, 1212, 1213, and 1214.

  Then, the wireless communication apparatus 100 performs two-dimensional frequency and time-axis subcarriers on frequencies f2, f5, f8, f9, f10, and f11 whose reception level is less than a predetermined level for chips on which data is spread. Place with. For example, chips obtained by spreading certain transmission data are arranged at positions 1221, 1222, 1223, and 1224, respectively.

  FIG. 13 is a block diagram illustrating an example of the configuration of the demapping unit of the wireless communication apparatus according to the present embodiment. 9 identical to those in FIG. 9 are assigned the same reference numerals as in FIG. 9 and detailed descriptions thereof are omitted.

  A demapping unit 805 in FIG. 13 includes a two-dimensional demapping unit 1301 instead of the frequency direction demapping unit 904. The two-dimensional demapping unit 1301 collects chips arranged two-dimensionally in the frequency direction and the time axis direction on subcarriers with a poor propagation path environment, and outputs the data to the switch 905.

  In this way, for subcarriers with a poor propagation path environment, chips on which data is spread are arranged two-dimensionally in the frequency direction and the time axis direction.

  In the above description, regarding the channel estimation unit 806 and the determination unit 807 on the receiver side, the channel estimation value based on the reception data of the frame is used as the input of the determination unit. However, for example, when FDD is used, the channel of the previous frame The estimated value (input on the transmission side determination unit of the frame) may be stored and demapped based on the estimated value.

  In the case of the TDD scheme, a method may be used in which the wireless communication apparatuses on the transmission side and the reception side perform channel estimation based on the received signals, respectively, and the channel estimation value is not transmitted to the communication partner.

(Embodiment 2)
FIG. 14 is a block diagram showing a configuration of a wireless communication apparatus according to Embodiment 2 of the present invention. 1 identical to those in FIG. 1 are assigned the same reference numerals as in FIG. 1, and detailed descriptions thereof are omitted.

  The wireless communication apparatus 1400 of FIG. 14 includes an encoder 1401, a modulator 1402, a modulator 1403, a spreader 1404, a spreader 1405, and a mapping unit 1406, and information on encoded data. 1 differs from FIG. 1 in that chips are arranged on subcarriers in two dimensions in the frequency direction and in the time direction for bits, and chips are arranged on subcarriers in the time direction for parity bits. The mapping unit 1406 includes a two-dimensional mapping unit 1407 and a time direction mapping unit 1408.

  In FIG. 14, encoder 1401 encodes data to be transmitted, outputs information bits of data to modulator 1402, and outputs parity bits to modulator 1403. Modulator 1402 modulates the information bits and outputs the modulated information bits to spreader 1404. The modulator 1403 modulates the parity bit and outputs it to the spreader 1405.

  The spreader 1404 multiplies the information bits by the spreading code and outputs the result to the two-dimensional mapping unit 1407. The spreader 1405 multiplies the parity bit by the spreading code and outputs the result to the time direction mapping unit 1408.

  The two-dimensional mapping unit 1407 arranges the chip in which the information bits are spread on the subcarrier in two dimensions in the frequency direction and the time axis direction, and outputs the subcarrier to the IFFT unit 107. The time direction mapping unit 1408 arranges the chip in which the parity bits are spread on the subcarrier in the time direction and outputs the chip to the IFFT unit 107.

  Next, mapping of radio communication apparatus 1400 according to the present embodiment will be described. FIG. 15 is a diagram illustrating an example of data after spreading. Each of the data in FIG. 15 has a spreading factor of 4, and one data is spread on four chips. In FIG. 15, the data is encoded at a coding rate of ½, the information bits are 4 bits 1501 to 1504, and the parity bits are 4 bits 1501 to 1508.

  FIG. 16 is a diagram illustrating an example in which data is arranged on subcarriers. In FIG. 16, the vertical axis represents frequency and the horizontal axis represents time. In FIG. 16, the wireless communication device 1400 arranges information bits 1501 to 1504 two-dimensionally with two chips in the frequency direction and two chips in the time direction. Radio communication apparatus 1400 arranges parity bits 1505-1508 in the time direction.

  Next, a wireless communication apparatus that receives data transmitted by the wireless communication apparatus 1400 will be described. FIG. 17 is a block diagram showing a configuration of a wireless communication apparatus according to Embodiment 2 of the present invention. 8 identical to those in FIG. 8 are assigned the same reference numerals as in FIG. 8 and detailed descriptions thereof are omitted.

  The wireless communication apparatus 1700 of FIG. 17 includes a demapping unit 1701, a despreader 1702, a despreader 1703, a demodulator 1704, a demodulator 1705, and a decoder 1706, and is encoded. For information bits of data, chips arranged in subcarriers in two dimensions in the frequency direction and in the time direction are combined into one information bit, and for parity bits, chips arranged in subcarriers in the time direction are combined into one parity bit. Different from the wireless communication apparatus of FIG. The demapping unit 1701 includes a two-dimensional demapping unit 1707 and a time direction demapping unit 1708.

  The FFT unit 804 performs fast Fourier transform on the received signal and outputs the converted received signal to the two-dimensional demapping unit 1707 and the time direction demapping unit 1708.

  The two-dimensional demapping unit 1707 collects chips arranged on each subcarrier in two dimensions in the frequency direction and the time direction into one information bit and outputs the information bits to the despreader 1702. The time direction demapping unit 1708 combines the chips arranged on each subcarrier in the frequency direction into one parity bit, and outputs it to the despreader 1703.

  The despreader 1702 despreads the rearranged information bits by multiplying them by a spreading code, and outputs the result to the demodulator 1704. The despreader 1703 multiplies the rearranged parity bits by a spreading code, despreads the result, and outputs the result to the demodulator 1705.

  The demodulator 1704 demodulates the information bits and outputs it to the decoder 1706. The demodulator 1705 demodulates the parity bit and outputs it to the decoder 1706. A decoder 1706 decodes data from the information bits and the parity bits.

  As described above, according to the wireless communication apparatus of the present embodiment, in OFDM-CDMA communication, a chip in which information bits are spread is arranged on a subcarrier in two dimensions in the frequency direction and the time direction, and a parity bit is spread. Is placed on subcarriers in the time direction, so that the level of information bits can be prevented from dropping extremely and the orthogonality of parity bits can be maintained, so that the characteristics of each bit necessary for error correction can be utilized. it can.

  In the above description, the subcarriers for time-direction spreading and two-dimensional spreading are completely separated, but there may be subcarriers to which both spreading methods are applied.

(Embodiment 3)
FIG. 18 is a block diagram showing a configuration of a wireless communication apparatus according to Embodiment 3 of the present invention. 1 identical to those in FIG. 1 are assigned the same reference numerals as in FIG. 1, and detailed descriptions thereof are omitted.

  The wireless communication apparatus 1800 of FIG. 18 includes an encoder 1801, an encoder 1802, a modulator 1803, a modulator 1804, a spreader 1805, a spreader 1806, and a mapping unit 1807. When transmitting data encoded at a plurality of different encoding rates, for data encoded at a high encoding rate, a chip in which the data is spread is arranged on the subcarrier in two dimensions in the frequency direction and the time direction, and low The data encoded at the coding rate is different from the wireless communication apparatus of FIG. 1 in that the chip in which the data is spread is arranged on the subcarrier in the time direction.

  The encoder 1801 encodes data to be transmitted and outputs the encoded data to the modulator 1803. Encoder 1802 encodes data to be transmitted at a lower coding rate than encoder 1801 and outputs the encoded data to modulator 1804.

  The modulator 1803 modulates the data and outputs it to the spreader 1805. Modulator 1804 modulates the data and outputs it to spreader 1806.

  The spreader 1805 multiplies the data by the spreading code and outputs the result to the mapping unit 1807. The spreader 1806 multiplies the data by the spreading code and outputs the result to the mapping unit 1807.

  The mapping unit 1807 arranges the chip on which the data is spread on the subcarrier in two dimensions in the frequency direction and the time direction for the data output from the spreader 1805, that is, the data that has been subjected to the coding process with a high coding rate. . Also, the mapping unit 1807 arranges the chip in which the data is spread on the subcarrier in the time direction for the data output from the spreader 1806, that is, the data subjected to the coding process with a low coding rate. Then, mapping section 1807 outputs data in which chips are arranged on subcarriers to IFFT section 107.

  Next, details of the mapping unit 1807 will be described. FIG. 19 is a block diagram illustrating an example of the configuration of the mapping unit of the wireless communication apparatus according to the present embodiment.

  The mapping unit 1807 in FIG. 19 mainly includes a two-dimensional mapping unit 1901, a time direction mapping unit 1902, and an adder 1903.

  The two-dimensional mapping unit 1901 arranges the data-spread chips on the subcarriers in two dimensions in the frequency direction and the time axis direction and outputs the data to the adder 1903 for the data encoded at a high encoding rate. The time direction mapping unit 1902 places data-spread chips on subcarriers in the time direction and outputs the data encoded at a low coding rate to the adder 1903.

  Adder 1903 adds the data output from two-dimensional mapping section 1901 and the data output from time direction mapping section 1902 for each subcarrier, and outputs the result to IFFT section 107.

  FIG. 20 is a diagram illustrating an example of data after spreading. The data in FIG. 20 includes data 2001 encoded at a low encoding rate and data 2002 to 2005 encoded at a higher encoding rate than data 2001. FIG. 21 is a diagram illustrating an example in which data is arranged on subcarriers. In FIG. 21, the vertical axis represents code multiplexing, and the horizontal axis represents frequency. Moreover, the axis | shaft of the diagonally right direction shows time.

  Low coding rate data 2001 arranges chips on subcarriers in the time direction, and high coding rate data 2002 to 2005 arranges chips on subcarriers in two dimensions in the frequency direction and time direction.

  Next, a wireless communication apparatus that receives data transmitted by wireless communication apparatus 1800 will be described. FIG. 22 is a block diagram showing a configuration of a wireless communication apparatus according to Embodiment 3 of the present invention. 8 identical to those in FIG. 8 are assigned the same reference numerals as in FIG. 8 and detailed descriptions thereof are omitted.

  In FIG. 22, a radio communication apparatus 2200 includes a demapping unit 2201, a despreader 2202, a despreader 2203, a demodulator 2204, a demodulator 2205, a decoder 2206, and a decoder 2207. For data encoded at a high coding rate, chips arranged on a subcarrier in two dimensions in the frequency direction and the time direction are combined into one information bit, and data encoded at a low coding rate is time direction 8 differs from the wireless communication apparatus of FIG. 8 in that the chips arranged on the subcarriers are combined into one parity bit.

  In FIG. 22, the FFT unit 804 performs fast Fourier transform on the received signal and outputs the converted received signal to the demapping unit 2201.

  The demapping unit 2201 collects chips arranged in each subcarrier in two dimensions in the frequency direction and the time direction as one information bit, outputs the information bits to the despreader 2202, and chips arranged in each subcarrier in the time direction. Are combined into one parity bit and output to the despreader 2203.

  Despreader 2202 multiplies the rearranged data by a spreading code, despreads the data, and outputs the result to demodulator 2204. The despreader 2203 despreads the rearranged data by multiplying the rearranged data by a spreading code, and outputs the result to the demodulator 2205.

  The demodulator 2204 demodulates the data and outputs it to the decoder 2206. The demodulator 2205 demodulates the data and outputs it to the decoder 2207.

  The decoder 2206 and the decoder 2207 decode data. The coding rate of data processed by the decoder 2206 corresponds to the encoder 1801, and the coding rate of data processed by the decoder 2207 corresponds to the encoder 1802. That is, the coding rate of data processed by the decoder 2206 is higher than the coding rate of data processed by the decoder 2207.

  Next, details of the demapping unit 2201 will be described. FIG. 23 is a block diagram illustrating an example of a configuration of a demapping unit of the wireless communication apparatus according to the present embodiment.

  The demapping unit 2201 in FIG. 23 mainly includes a two-dimensional demapping unit 2301 and a time direction demapping unit 2302.

  The two-dimensional demapping unit 2301 collects chips arranged on each subcarrier in two dimensions in the frequency direction and the time direction for data encoded at a high coding rate, and sets the information bits as one information bit. Output. The time direction demapping unit 2302 collects chips encoded on each subcarrier in the frequency direction for data encoded at a low encoding rate, and outputs the data to the despreader 2203.

  As described above, according to the wireless communication apparatus of the present embodiment, when data encoded with a plurality of different encoding rates is transmitted, a chip in which data is spread with respect to data encoded with a high encoding rate. Is placed on the subcarrier in two dimensions in the frequency direction and the time direction, and for data encoded at a low coding rate, the data-spread chip is placed on the subcarrier in the time direction, thereby encoding at a high coding rate. It is possible to prevent bits with extremely bad reception quality from being generated, and to prevent a state where a small number of parity bits are not received correctly and error correction is not performed correctly.

  In the above description, two types of coding rates are used, but three or more types of coding rates may be mixed. For example, for data encoded at a predetermined encoding rate or higher, data in which the chip in which the data is diffused is arranged on a subcarrier in two dimensions in the frequency direction and the time direction and encoded at less than a predetermined diffusion encoding rate For the above, a chip in which data is diffused may be arranged on a subcarrier in the time direction.

  In the above description, an example is described in which the spreading factor is 4, and one bit is diffused to four chips. However, the spreading factor is not limited, and any spreading factor can be applied.

(Embodiment 4)
FIG. 24 is a block diagram showing a configuration of a wireless communication apparatus according to Embodiment 4 of the present invention. 1 identical to those in FIG. 1 are assigned the same reference numerals as in FIG. 1, and detailed descriptions thereof are omitted.

  The radio communication apparatus 2400 of FIG. 24 includes an encoder 2401, a modulator 2402, a spreader 2403, a spreader 2404, and a mapping unit 2405. Symbols spread in the frequency axis direction are arranged in the time axis direction. 1 is different from the wireless communication apparatus of FIG. 1 in that it is spread at a higher spreading factor than the spread symbols. The mapping unit 2405 is mainly composed of a frequency direction mapping unit 2406 and a time direction mapping unit 2407.

  The encoder 2401 encodes data to be transmitted and outputs the encoded data to the modulator 2402. Modulator 2402 modulates data, outputs part of the modulated data to spreader 2403, and outputs another part of data to spreader 2404.

  The spreader 2403 spreads the data and outputs it to the frequency direction mapping unit 2406 in the mapping unit 2405. The spreader 2404 spreads the data with a lower spreading factor than the spreader 2403 and outputs the spread data to the time direction mapping unit 2407 in the mapping unit 2405.

  The frequency direction mapping unit 2406 arranges the chip in which the data is spread in the subcarrier in the frequency direction, and outputs the data in which the chip is arranged in the subcarrier to the IFFT unit 107. The time direction mapping unit 2407 arranges the chip in which the data is spread in the subcarrier in the time direction, and outputs the data in which the chip is arranged in the subcarrier to the IFFT unit 107.

  Next, details of the mapping unit 2405 will be described. FIG. 25 is a block diagram illustrating an example of the configuration of the mapping unit of the wireless communication apparatus according to the present embodiment.

  The mapping controller 2501 outputs the number of subcarriers whose propagation path condition is equal to or higher than a predetermined level to the time direction mapping section 2407, and outputs the number of subcarriers whose propagation path condition is lower than the predetermined level to the frequency direction mapping section 2406. Output to. Further, mapping controller 2501 outputs to switch 2502 the frequency of the subcarrier whose propagation path condition is equal to or higher than a predetermined level and the frequency of the subcarrier whose propagation path condition is lower than a predetermined level.

  The frequency direction mapping unit 2406 arranges the data spread from the spreader 2403 on the subcarrier in the frequency direction and outputs the chip to the switch 2502. The time direction mapping unit 2407 places chips spread at a low spreading factor on subcarriers in the time direction and outputs the chips to the switch 2502.

  The switch 2502 outputs the chip output from the time direction mapping unit 2407 to a subcarrier whose propagation path state is equal to or higher than a predetermined level, and the chip output from the frequency direction mapping unit 2406 has a propagation path state lower than a predetermined level. Is output to the subcarrier.

  With the above operation, the wireless communication apparatus 2400 maps data in a time axis direction to a carrier frequency whose propagation path condition is equal to or higher than a predetermined level, and spreads data spread at a higher spreading factor than data mapped in the time axis direction. Mapping is performed in the frequency direction to a carrier frequency whose propagation path condition is below a predetermined level.

  Next, an example in which data transmitted by the wireless communication device 2400 is received will be described. FIG. 26 is a block diagram showing a configuration of a wireless communication apparatus according to Embodiment 4 of the present invention.

  26 includes a demapping unit 2601, a despreader 2602, a despreader 2603, a demodulator 2604, and a decoder 2605, and is a symbol spread in the frequency axis direction 8 is different from the radio communication apparatus of FIG. 8 in that it is despread with a higher spreading factor than symbols spread in the time axis direction. The demapping unit 2601 mainly includes a frequency direction demapping unit 2606 and a time direction demapping unit 2607.

  In accordance with the determination result of the determination unit 807, the demapping unit 2601 collects chips arranged in the time axis direction as one data for the received signals of subcarriers whose propagation path state is equal to or higher than a predetermined level. For received signals of subcarriers having a value less than a predetermined level, chips arranged in the frequency direction are collected as one data.

  The despreader 2602 despreads the rearranged data and outputs it to the demodulator 2604. The despreader 2603 despreads the rearranged data with a lower spreading factor than the despreader 2602 and outputs the despread data to the demodulator 2604. The demodulator 2604 demodulates the received data and outputs it to the decoder 2605. The decoder 2605 decodes the received data.

  Next, details of the demapping unit 2601 will be described. FIG. 27 is a block diagram illustrating an example of a configuration of the demapping unit of the wireless communication apparatus according to the present embodiment. The demapping unit 2601 in FIG. 27 mainly includes a demapping controller 2701, a switch 2702, a frequency direction demapping unit 2606, and a time direction demapping unit 2607.

  The demapping controller 2701 controls the switch 2702 based on the determination result output from the determination unit 807. Further, the demapping controller 2701 outputs to the switch 2702 the frequency of the subcarrier whose propagation path condition is equal to or higher than a predetermined level and the frequency of the subcarrier whose propagation path condition is lower than a predetermined level.

  The demapping controller 2701 outputs the number of subcarriers whose propagation path condition is greater than or equal to a predetermined level to the time direction demapping unit 2607, and calculates the number of subcarriers whose propagation path condition is less than the predetermined level. The data is output to the mapping unit 2606.

  The switch 2702 outputs a received signal transmitted on a subcarrier whose propagation path condition is equal to or higher than a predetermined level to the time direction demapping unit 2607, and received on a subcarrier whose propagation path condition is lower than a predetermined level. The signal is output to frequency direction demapping section 2606.

  The time direction demapping unit 2607 collects chips arranged on each subcarrier in the time direction as one data and outputs the data to the despreader 2603. The frequency direction demapping unit 2606 collects chips arranged on each subcarrier in the frequency direction as one data and outputs the data to the despreader 2602.

  As described above, according to the radio communication apparatus of the present embodiment, in OFDM-CDMA communication, symbols spread in the frequency axis direction are spread at a higher spreading factor than symbols spread in the time axis direction, and transmission data is spread. The chip is arranged in the time direction by arranging in the time axis direction a subcarrier having a better propagation path environment than a predetermined level, and in the frequency direction on a subcarrier having a worse propagation path environment than the predetermined level. Both of the effect of maintaining orthogonality between spreading codes when spreading and the frequency diversity effect when spreading chips in the frequency direction can be obtained simultaneously.

(Embodiment 5)
FIG. 28 is a block diagram showing a configuration of a wireless communication apparatus according to Embodiment 5 of the present invention. 1 identical to those in FIG. 1 are assigned the same reference numerals as in FIG. 1, and detailed descriptions thereof are omitted.

  The radio communication apparatus 2800 of FIG. 28 includes an encoder 2801, a modulator 2802, a modulator 2803, a spreader 2804, a spreader 2805, and a mapping unit 2806, and a symbol spread in the time axis direction. 1 is different from the radio communication apparatus of FIG. 1 in that modulation is performed using a modulation scheme in which the multi-level number of information that can be transmitted in one symbol is higher than symbols that are spread in the frequency axis direction. The mapping unit 2806 mainly includes a frequency direction mapping unit 2807 and a time direction mapping unit 2808.

  The encoder 2801 encodes data to be transmitted, outputs a part of the encoded data to the modulator 2802, and outputs another part of the data to the modulator 2803.

  Modulator 2802 modulates the data and outputs it to spreader 2804. Modulator 2803 modulates the data with a modulation scheme having a higher multi-valued number of information that can be transmitted in one symbol than modulator 2802 and outputs the result to spreader 2805. For example, the modulator 2802 modulates with BPSK or QPSK, and the modulator 2803 modulates with 16QAM or 64QAM.

  The spreader 2804 spreads the data and outputs it to the frequency direction mapping unit 2807 in the mapping unit 2806. The spreader 2805 spreads the data and outputs it to the time direction mapping unit 2808 in the mapping unit 2806.

  The frequency direction mapping unit 2807 arranges the chip in which the data is spread in the subcarrier in the frequency direction, and outputs the data in which the chip is arranged in the subcarrier to the IFFT unit 107. The time direction mapping unit 2808 arranges the chip in which the data is spread in the subcarrier in the time direction, and outputs the data in which the chip is arranged in the subcarrier to the IFFT unit 107.

  Next, details of the mapping unit 2806 will be described. FIG. 29 is a block diagram illustrating an example of the configuration of the mapping unit of the wireless communication apparatus according to the present embodiment.

  The mapping controller 2901 outputs the number of subcarriers having a propagation path condition equal to or higher than a predetermined level to the time direction mapping section 2808, and sets the number of subcarriers having a propagation path condition less than the predetermined level to the frequency direction mapping section 2807. Output to. Further, mapping controller 2901 outputs to switch 2902 the frequency of the subcarrier whose propagation path condition is equal to or higher than a predetermined level and the frequency of the subcarrier whose propagation path condition is lower than a predetermined level.

  The frequency direction mapping unit 2807 places the chip in which the data is spread on the subcarrier in the frequency direction and outputs the data output from the spreader 2804 to the switch 2902. The time direction mapping unit 2808 places the chip in which the data is spread on the subcarrier in the time direction for the data modulated by the modulation scheme having a high multilevel number, and outputs it to the switch 2902.

  The switch 2902 outputs the chip output from the time direction mapping unit 2808 to a subcarrier whose propagation path state is a predetermined level or higher, and the chip output from the frequency direction mapping unit 2807 has a propagation path state lower than a predetermined level. Is output to the subcarrier.

  Through the above operation, radio communication apparatus 2800 maps data in the frequency direction to a carrier frequency whose propagation path condition is less than a predetermined level, and transmits more information than one symbol spread in the frequency axis direction. The data modulated by the modulation method having a high value number is mapped in the time axis direction to the carrier frequency whose propagation path condition is equal to or higher than a predetermined level.

  Next, an example of receiving data transmitted by the wireless communication device 2800 will be described. FIG. 30 is a block diagram showing a configuration of a radio communication apparatus according to Embodiment 5 of the present invention.

  30 includes a demapping unit 3001, a despreader 3002, a despreader 3003, a demodulator 3004, a demodulator 3005, and a decoder 3006 in the time axis direction. 8 is different from the radio communication apparatus of FIG. 8 in that a symbol after despreading of spread data is demodulated by a demodulation method having a higher multi-value number than a symbol after despreading of data spread in the frequency direction. The demapping unit 3001 mainly includes a frequency direction demapping unit 3007 and a time direction demapping unit 3008.

  In accordance with the determination result of the determination unit 807, the demapping unit 3001 collects chips arranged in the time axis direction as a single data for the received signals of subcarriers whose propagation path state is equal to or higher than a predetermined level. For received signals of subcarriers having a value less than a predetermined level, chips arranged in the frequency direction are collected as one data.

  The despreader 3002 despreads the rearranged data and outputs it to the demodulator 3004. The despreader 3003 despreads the rearranged data and outputs it to the demodulator 3005.

  The demodulator 3004 demodulates the received data and outputs it to the decoder 3006. Demodulator 3005 demodulates the received data with a modulation scheme having a higher multi-level number of information that can be transmitted in one symbol than demodulator 3004 and outputs the demodulated data to decoder 3006. For example, the demodulator 3004 demodulates with BPSK or QPSK, and the demodulator 3005 demodulates with 16QAM or 64QAM. Decoder 3006 decodes the received data.

  Next, details of the demapping unit 3001 will be described. FIG. 31 is a block diagram illustrating an example of a configuration of the demapping unit of the wireless communication apparatus according to the present embodiment. The demapping unit 3001 in FIG. 31 mainly includes a demapping controller 3101, a switch 3102, a frequency direction demapping unit 3007, and a time direction demapping unit 3008.

  The demapping controller 3101 controls the switch 3102 based on the determination result output from the determination unit 807. Further, the demapping controller 3101 outputs to the switch 3102 the frequency of the subcarrier whose propagation path condition is equal to or higher than a predetermined level and the frequency of the subcarrier whose propagation path condition is lower than a predetermined level.

  The demapping controller 3101 outputs the number of subcarriers whose propagation path condition is greater than or equal to a predetermined level to the time direction demapping unit 3008, and calculates the number of subcarriers whose propagation path condition is less than the predetermined level in the frequency direction demapper. The data is output to the mapping unit 3007.

  The switch 3102 outputs a reception signal transmitted on a subcarrier whose propagation path condition is equal to or higher than a predetermined level to the time direction demapping unit 3008, and reception received on a subcarrier whose propagation path condition is lower than a predetermined level. The signal is output to the frequency direction demapping unit 3007.

  The time direction demapping unit 3008 collects chips arranged on each subcarrier in the time direction as one data and outputs the data to the despreader 3003. The frequency direction demapping unit 3007 collects chips arranged on each subcarrier in the frequency direction as one data, and outputs the data to the despreader 3002.

  As described above, according to the radio communication apparatus of the present embodiment, in OFDM-CDMA communication, multiple values of information that can be transmitted with a symbol spread in the time axis direction as one symbol rather than symbols spread in the frequency axis direction. The arrangement of chips that are modulated by a modulation method with a high number and in which transmission data is spread is arranged in the time axis direction on subcarriers with a better propagation path environment than a predetermined level, while the multivalue number is low or multivalue By arranging spreading chips of data modulated by a modulation method not used in the frequency direction on subcarriers whose propagation path environment is worse than a predetermined level, the orthogonality between spreading codes when the chips are spread in the time direction can be increased. Both the effect of maintaining and the frequency diversity effect when the chip is diffused in the frequency direction can be obtained simultaneously.

  The mapping in the frequency direction described above may be performed in two dimensions, the time axis and the frequency axis.

  Further, the modulator and demodulator described above are described as a combination of BPSK or QPSK and 16QAM or 64QAM, but the multilevel modulation / demodulation system is not limited to the above.

  In the above description, inverse fast Fourier transform and fast Fourier transform are used as a method of superimposing data on a plurality of subcarriers, but orthogonal transform such as discrete cosine transform may be used.

  In the present invention, there is no limitation on the order in which chips are arranged in the time direction and the arrangement of chips in the frequency direction, and either may be performed first.

  The present invention is not limited to the above-described embodiment, and can be implemented with various modifications. For example, in the above-described embodiment, the case of performing as a wireless communication device has been described. However, the present invention is not limited to this, and the wireless communication method can be performed as software.

  For example, a program for executing the wireless communication method may be stored in advance in a ROM (Read Only Memory), and the program may be operated by a CPU (Central Processor Unit).

  Also, a program for executing the above wireless communication method is stored in a computer-readable storage medium, the program stored in the storage medium is recorded in a RAM (Random Access memory) of the computer, and the computer operates according to the program. You may make it let it.

  The present invention is suitable for use in a radio communication apparatus, a communication terminal apparatus, and a base station apparatus that combine OFDM and CDMA.

1 is a block diagram showing a configuration of a wireless communication apparatus according to Embodiment 1 of the present invention. Diagram showing an example of channel fluctuation in the frequency direction Diagram showing an example of channel fluctuation on the time axis The figure which shows an example of chip arrangement | positioning of the radio | wireless communication apparatus of the said embodiment The block diagram which shows an example of a structure of the mapping part of the radio | wireless communication apparatus of the said embodiment Diagram showing an example of data after spreading The figure which shows an example which has arranged data on a subcarrier 1 is a block diagram showing a configuration of a wireless communication apparatus according to Embodiment 1 of the present invention. The block diagram which shows an example of a structure of the demapping part of the radio | wireless communication apparatus of the said embodiment The block diagram which shows an example of a structure of the mapping part of the radio | wireless communication apparatus of the said embodiment Diagram showing an example of channel fluctuation in the frequency direction The figure which shows an example of chip arrangement | positioning of the radio | wireless communication apparatus of the said embodiment The block diagram which shows an example of a structure of the demapping part of the radio | wireless communication apparatus of the said embodiment FIG. 2 is a block diagram showing a configuration of a wireless communication apparatus according to Embodiment 2 of the present invention. Diagram showing an example of data after spreading The figure which shows an example which has arranged data on a subcarrier FIG. 2 is a block diagram showing a configuration of a wireless communication apparatus according to Embodiment 2 of the present invention. Block diagram showing the configuration of a wireless communication apparatus according to Embodiment 3 of the present invention FIG. 2 is a block diagram illustrating an example of a configuration of a mapping unit of the wireless communication apparatus according to the present embodiment Diagram showing an example of data after spreading The figure which shows an example which has arranged data on a subcarrier Block diagram showing the configuration of a wireless communication apparatus according to Embodiment 3 of the present invention The block diagram which shows an example of a structure of the demapping part of the radio | wireless communication apparatus of the said embodiment Block diagram showing the configuration of a wireless communication apparatus according to Embodiment 4 of the present invention The block diagram which shows an example of a structure of the mapping part of the radio | wireless communication apparatus of the said embodiment Block diagram showing the configuration of a wireless communication apparatus according to Embodiment 4 of the present invention The block diagram which shows an example of a structure of the demapping part of the radio | wireless communication apparatus of the said embodiment Block diagram showing a configuration of a wireless communication apparatus according to a fifth embodiment of the present invention The block diagram which shows an example of a structure of the mapping part of the radio | wireless communication apparatus of the said embodiment Block diagram showing a configuration of a wireless communication apparatus according to a fifth embodiment of the present invention The block diagram which shows an example of a structure of the demapping part of the radio | wireless communication apparatus of the said embodiment

101, 1401, 1801, 1802 Encoder 102, 1402, 1403, 1803, 1804 Modulator 103, 1404, 1405, 1805, 1806 Spreader 104, 801 Radio reception unit 105, 807 Determination unit 106, 1406, 1807 Mapping unit 107 IFFT unit 108 P / S converter 110, 808 Wireless transmission unit 501 Mapping controller 502, 505, 902, 905 Switch 503, 1408, 1902 Time direction mapping unit 504 Frequency direction mapping unit 803 S / P converter 804 FFT unit 805, 1701, 2201 Demapping unit 806 Channel estimation unit 809, 1702, 1703, 2202, 2203 Despreader 810, 1704, 1705, 2204, 2205 Demodulator 811, 1706, 2 06,2207 decoder 901 demaps controller 903,1708,2302 hours direction demapping unit 904 frequency domain demapping section 1001,1407,1901 two-dimensional mapping unit 1301,1707,2301 two-dimensional demapping section 1903 adder

Claims (9)

A plurality of second modulations including a modulation method in which the first data is modulated using one of the plurality of first modulation methods and the modulation multi-level number is different from that of the first modulation method. A modulation unit that modulates the second data using one of the modulation methods;
An arrangement unit that arranges the modulated first data on a plurality of subcarriers in a time axis direction, and arranges the modulated second data on a plurality of subcarriers in a frequency axis direction;
I have a,
The first modulation scheme includes 16QAM or 64QAM, the second modulation scheme includes BPSK or QPSK,
The arrangement unit arranges the first data on the plurality of subcarriers having better propagation path conditions than a predetermined level.
Communication device. An encoding unit that encodes the first data at a first encoding rate and encodes the second data at a second encoding rate different from the first encoding rate; ,
The modulation unit modulates the encoded first data and the encoded second data ;
The arrangement unit arranges the modulated second data in a plurality of subcarriers in a frequency axis direction and a time axis direction.
The communication apparatus according to claim 1 . An encoding unit that encodes the first data at a first encoding rate and encodes the second data at a second encoding rate that is higher than the first encoding rate; ,
The modulation unit modulates the encoded first data and the encoded second data ;
The arrangement unit arranges the modulated second data in a plurality of subcarriers in a frequency axis direction and a time axis direction.
The communication apparatus according to claim 1 or 2 . A diffusion unit for diffusing the first data with a first spreading factor and diffusing the second data with a second spreading factor different from the first spreading factor;
The modulating unit modulates the spread first data and the spread second data;
Communication apparatus according to any one of claims 1 to 3. A diffusion unit for diffusing the first data with a first spreading factor and diffusing the second data with a second spreading factor higher than the first spreading factor;
The modulating unit modulates the spread first data and the spread second data;
Communication apparatus according to any one of claims 1 to 4. Arranged in a time axis direction on a plurality of subcarriers, receives first data modulated using one of a plurality of first modulation schemes, and arranged in a frequency axis direction on a plurality of subcarriers A receiver that receives second data modulated using one of a plurality of second modulation schemes including a modulation scheme different from the first modulation scheme in the modulation multi-level number; ,
A demodulator that demodulates the received first data and the received second data;
I have a,
The first modulation scheme includes 16QAM or 64QAM, the second modulation scheme includes BPSK or QPSK,
The first data is arranged on the plurality of subcarriers having a better propagation path condition than a predetermined level.
Communication device. The demodulator demodulates the first data using the first modulation scheme, and demodulates the second data using the second modulation scheme.
The communication apparatus according to claim 6 . Modulating the first data using one of a plurality of first modulation schemes;
Modulating the second data using one of a plurality of second modulation schemes including a modulation scheme having a modulation multi-level number different from the first modulation scheme;
The modulated first data is arranged in a time axis direction on a plurality of subcarriers,
The modulated second data is arranged in the frequency axis direction on a plurality of subcarriers ,
The first modulation scheme includes 16QAM or 64QAM, the second modulation scheme includes BPSK or QPSK,
The first data is arranged on the plurality of subcarriers having a better propagation path condition than a predetermined level.
Communication method. Receiving first data that is arranged in a time axis direction on a plurality of subcarriers and modulated using one of a plurality of first modulation schemes;
Arranged in the frequency axis direction on a plurality of subcarriers and modulated using one of a plurality of second modulation schemes including a modulation scheme different from the first modulation scheme. Receiving the second data,
Demodulating the received first data and the received second data ;
The first modulation scheme includes 16QAM or 64QAM, the second modulation scheme includes BPSK or QPSK,
The first data is arranged on the plurality of subcarriers having a better propagation path condition than a predetermined level.
Communication method.

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