JP2006173866A - Transmission apparatus and transmission method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a transmission apparatus and a transmission method capable of enhancing the reception quality while decreasing the number of retransmission times. <P>SOLUTION: A puncture section 102 applies puncture processing to a parity bit sequence on the basis of a coding rate outputted from a coding rate determining section 110. An IFFT section 104 respectively assigns a systematic bit sequence and the parity bit sequence to segments according to an instruction of a segment assigning section 112 and applies IFFT processing to the segments to generate a multicarrier signal. The coding rate determining section 110 stores a coding rate table wherein propagation channel information and the coding rate are associated in advance, and determines the coding rate corresponding to the received propagation channel information on the basis of the coding rate table. A time/frequency correlation value calculation section 111 calculates a frequency interval equivalent to the correlation value of the propagation path characteristic at a time interval between transmission processes in the case of carrying out ordinary HARQ. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a transmission apparatus and a transmission method, and more particularly to a transmission apparatus and a transmission method for performing retransmission control according to an ACK / NACK signal fed back from a reception side and transmitting a multicarrier signal including a plurality of carriers having different frequencies.

  Conventionally, as a data transmission method for realizing error-free in wireless communication, an error correction coding method such as turbo coding and an automatic repeat request method for retransmitting transmission data when a transmission error occurs on the receiving side (Automatic Repeat) Request: hereinafter abbreviated as “ARQ”). In recent years, hybrid ARQ (hereinafter abbreviated as “HARQ”), which combines an error correction coding method and ARQ, has attracted attention, and is also standardized by 3GPP, which is a standardization organization for third-generation mobile communication methods. Has been.

  In HARQ, for example, a receiving device such as a mobile terminal, for example, correctly receives a signal from a transmitting device such as a base station using an error detection code (Cyclic Redundancy Check: hereinafter abbreviated as “CRC”). In the case of correct reception, an ACK signal is fed back (transmitted) to the transmitting apparatus.

  When the received signal is an ACK signal, the transmitting device performs transmission processing of a new signal. On the other hand, when the received signal is a NACK signal, the transmitting device performs retransmission processing of the signal sent to the previous receiving device. Do. In the retransmission process, not all of the signal sent to the receiving device last time but adaptively sending a part thereof (only systematic bits that are information bits, only parity bits that are redundant bits, or a combination thereof) The transmission rate is relatively increased.

  HARQ, on the other hand, requires the receiving device to hold the data transmitted from the transmitting device before the retransmission is completed, and therefore the memory of the receiving device increases significantly, and the parity bit is divided. Therefore, there is a problem that transmission delay increases.

In order to solve the above problem, it is necessary to complete the transmission with as few retransmissions as possible, ideally with only one retransmission. Specifically, there is a method of transmitting the parity bits that have been divided and transmitted multiple times at the time of the first retransmission (see, for example, Patent Documents 1 and 2).
JP 7-336331 A JP-T-2002-527939

  However, if the number of retransmissions is reduced as described above, there is a problem that high reception quality due to time diversity gain is lost. That is, when the parity bit is divided and transmitted a plurality of times, the transmission delay increases, but the correlation of the propagation environment between the initial transmission and the final retransmission decreases, so that a time diversity gain is obtained. On the other hand, if the number of retransmissions is reduced, the time interval between the first transmission and the last retransmission is reduced, the correlation of the propagation environment is increased, and the time diversity gain cannot be obtained. Therefore, if the number of retransmissions is small, the reception quality in the receiving apparatus may not be greatly improved even if the same number of parity bits are transmitted as when the parity bits are divided and transmitted multiple times.

  SUMMARY An advantage of some aspects of the invention is that it provides a transmission apparatus and a transmission method capable of improving reception quality while reducing the number of retransmissions.

  A transmitting apparatus according to the present invention encodes transmission data addressed to the receiving apparatus at an encoding rate according to the propagation channel information, an acquisition unit that acquires propagation channel information indicating a propagation channel environment with the receiving apparatus Encoding means for converting, calculating means for calculating a frequency interval according to the propagation channel information, and assigning means for assigning the encoded transmission data to a segment of a frequency separated by the calculated frequency interval or more Take.

  The transmission method according to the present invention includes a step of obtaining propagation channel information indicating an environment of a propagation channel with a receiving device, and encoding transmission data addressed to the receiving device at a coding rate according to the propagation channel information. And a step of calculating a frequency interval according to the propagation channel information, and a step of assigning encoded transmission data to a segment having a frequency separated by at least the calculated frequency interval.

  According to these, in order to transmit transmission data at a coding rate and a frequency interval according to propagation channel information, all systematic bit sequences and parity bits that are divided and transmitted multiple times when performing normal HARQ In addition to transmitting the sequences collectively, the decrease in time diversity gain due to the decrease in the number of transmissions can be compensated by the frequency diversity gain, and the reception quality can be improved while reducing the number of retransmissions.

  According to the present invention, it is possible to improve reception quality while reducing the number of retransmissions.

  The essence of the present invention is to superimpose systematic bits and parity bits destined for the same receiving apparatus on different carriers separated in the frequency direction so that a frequency diversity gain corresponding to the time diversity gain can be obtained.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

  In the present embodiment, as a result of reception of a signal transmitted from transmission apparatus 100 by reception apparatus 200 and detection of an error in the reception signal, reception apparatus 200 receives an ACK indicating that the signal has been received without error or A NACK requesting retransmission of the signal is fed back to the transmitting apparatus 100.

  FIG. 1 is a block diagram showing a configuration of transmitting apparatus 100 according to the present embodiment. 1, a transmission apparatus 100 includes an error correction coding unit 101, a puncture unit 102, a digital modulation unit 103, an IFFT (Inverse Fast Fourier Transform) unit 104, and a GI (Guard Interval) insertion unit. 105, a transmission RF (Radio Frequency) unit 106, a reception RF unit 107, an ACK / NACK detection unit 108, a propagation channel information demodulation unit 109, a coding rate determination unit 110, a time / frequency correlation value calculation unit 111, and A segment allocation unit 112 is included.

  Error correction coding section 101 performs error correction coding on transmission data for the purpose of improving error correction capability, and outputs the obtained systematic bit sequence and parity bit sequence to puncturing section 102.

  Puncturing section 102 performs puncturing processing on the parity bit sequence based on the coding rate output from coding rate determining section 110, and outputs the systematic bit sequence and the punctured parity bit sequence to digital modulation section 103. To do.

  The digital modulation unit 103 digitally modulates the systematic bit sequence and the parity bit sequence output from the puncturing unit 102 and outputs the modulated systematic bit sequence and the parity bit sequence to the IFFT unit 104.

  IFFT section 104 allocates systematic bit sequences and parity bit sequences to segments in accordance with instructions from segment allocation section 112 and performs IFFT processing to generate a multicarrier signal. Here, the segment is a group composed of a plurality of carriers having different frequencies.

  GI insertion section 105 inserts a guard interval between each symbol of the multicarrier signal, and outputs the multicarrier signal after the insertion of the guard interval to transmission RF section 106.

  The transmission RF unit 106 performs transmission processing (D / A conversion, up-conversion to a radio frequency band, etc.) on the multicarrier signal output from the GI insertion unit 105, and transmits it via an antenna. Further, the transmission RF unit 106 transmits segment information related to segment allocation by the segment allocation unit 112 and coding rate information indicating the coding rate determined by the coding rate determination unit 110.

  The reception RF unit 107 receives the ACK / NACK signal fed back from the reception apparatus 200 and propagation channel information such as delay spread and maximum Doppler frequency, and performs predetermined reception processing (down-conversion, A / D conversion) on the reception signal. Etc.).

  The ACK / NACK detection unit 108 detects an ACK / NACK signal from the received signal, and notifies the segment allocation unit 112 whether ACK is received or NACK is received.

  Propagation channel information demodulation section 109 extracts the propagation channel information from the received signal, demodulates the extracted propagation channel information, and outputs it to coding rate determination section 110 and time / frequency correlation value calculation section 111.

  The coding rate determining unit 110 holds a coding rate table in which the propagation channel information is associated with the coding rate in advance, and the propagation channel output from the propagation channel information demodulating unit 109 based on the coding rate table A coding rate corresponding to the information is determined. Specifically, when assuming that normal HARQ is performed, the coding rate determination unit 110 changes each parameter and ACK signal when parameters included in propagation channel information such as delay spread and maximum Doppler frequency change. Is stored in advance in association with the number of parity bits to be transmitted until reception of the data (that is, until retransmission is completed). Then, the coding rate determination unit 110 reads the number of parity bits corresponding to the propagation channel information output from the propagation channel information demodulation unit 109 from the held coding rate table, and determines the coding rate.

The time / frequency correlation value calculation unit 111 is in a time interval between transmissions when performing normal HARQ (that is, for example, from the completion of the first transmission until the first retransmission is started after the ACK / NACK signal is received). A frequency interval corresponding to the correlation value of the propagation path characteristic is calculated. Specifically, the time / frequency correlation value calculation unit 111 first sets the time correlation value ρ _t (RTT) of the propagation path characteristic corresponding to the time interval RTT between transmissions when performing normal HARQ as Calculate from (1). In Equation (1), f _D is the maximum Doppler frequency included in the propagation channel information, and J ₀ is the 0th order Bessel function.

ρ _t (RTT) = J ₀ (2πf _D RTT) (1)
Note that the time / frequency correlation value calculation unit 111 assumes that normal HARQ is performed and each parameter and ACK signal when the parameters included in the propagation channel information such as the delay spread and the maximum Doppler frequency change are changed. A retransmission number table is stored in which the number of retransmissions until reception (that is, until all retransmissions are completed) and the time required for retransmission are associated with each other. Therefore, the time / frequency correlation value calculation unit 111 refers to this retransmission count table to determine the time interval RTT corresponding to the propagation channel information output from the propagation channel information demodulation unit 109, and the above equation (1) Perform the operation.

The time correlation value ρ _t (RTT) is an index indicating the time diversity gain that decreases as the number of retransmissions decreases. That is, it can be considered that the smaller the time correlation value ρ _t (RTT), the larger the fluctuation of the propagation path characteristic in the time interval RTT, and the larger the time diversity gain that is reduced by reducing the number of retransmissions.

Next, the time / frequency correlation value calculation unit 111 calculates the frequency correlation value ρ _f (B _seg ) between the segments whose frequency interval is B _seg expressed by the following equation (2) and the equation (1). From the obtained time correlation value ρ _t (RTT), a frequency interval B _{seg at} which the frequency correlation value ρ _f (B _seg ) is equal to or smaller than the time correlation value ρ _t (RTT) is obtained. In Equation (2), τ _rms is a delay spread included in the propagation channel information.

ここでも同様に、周波数相関値ρ_f(B_seg)が小さいほど周波数間隔B_segに対応する伝搬路特性の差が大きく、周波数ダイバーシチによって得られる利得は大きいと考えられる。

Similarly, it is considered that the smaller the frequency correlation value ρ _f (B _seg ), the larger the difference in propagation path characteristics corresponding to the frequency interval B _seg , and the larger the gain obtained by frequency diversity.

Therefore, the time / frequency correlation value calculation unit 111 obtains a frequency interval B _seg that satisfies the condition of the following expression (3), and thereby compensates the time diversity gain when performing normal HARQ by one transmission. The interval can be determined. That is, at two frequencies separated by a frequency interval B _{seg that} satisfies the following expression (3), the time in the time interval RTT between each transmission (ie, initial transmission and each retransmission) when performing normal HARQ A frequency diversity gain equal to or greater than the diversity gain can be obtained. Therefore, the time that should be obtained by retransmission by allocating data for one retransmission when performing normal HARQ to subcarriers of frequencies separated from each other by a frequency interval B _{seg that} satisfies the condition of the following expression (3): A frequency diversity gain greater than the diversity gain can be obtained.

ρ _f (B _seg ) ≦ ρ _t (RTT) (3)
Furthermore, the time / frequency correlation value calculation section 111, by the equation (3) satisfy the frequency interval the following equation from B _seg (4) of calculating the number of segments x contained in the frequency interval B _seg. In Expression (4), ΔF is a frequency interval per segment.

このように、時間／周波数相関値算出部１１１は、上記式（１）〜（４）から、通常のＨＡＲＱを行った場合に得られる時間ダイバーシチ利得を補償する周波数間隔に対応するセグメント数ｘを算出し、セグメント割当部１１２に出力する。

As described above, the time / frequency correlation value calculation unit 111 calculates the number of segments x corresponding to the frequency interval for compensating the time diversity gain obtained when performing normal HARQ from the above formulas (1) to (4). Calculate and output to the segment allocation unit 112.

  When the ACK is received, the segment allocation unit 112 determines the segment allocation so that the systematic bit sequence and the parity bit sequence addressed to the same receiving apparatus are arranged at intervals of the number of segments x or more, and the NACK is received. In this case, the segment allocation is determined so that the retransmission parity bit sequence is arranged in the segment to which the previous systematic bit sequence has been allocated. That is, when the ACK is received and the new transmission data is transmitted, the segment allocation unit 112 sets the systematic bit sequence and the parity bit sequence every more than the number of segments x calculated by the time / frequency correlation value calculation unit 111. Decide which segment allocation to place. For this reason, all systematic bits and parity bits transmitted when performing normal HARQ are transmitted at the time of initial transmission, and the decrease in time diversity gain due to the decrease in the number of retransmissions is compensated by the frequency diversity gain. The On the other hand, in the case where NACK is received and the transmitted transmission data is retransmitted, the segment allocation unit 112 arranges a parity bit sequence for retransmission in a segment in which a systematic bit sequence is arranged at the time of initial transmission of this transmission data. Determine the assignment.

  FIG. 2 is a block diagram showing a configuration of receiving apparatus 200 according to the present embodiment. In FIG. 2, a receiving apparatus 200 includes a reception RF unit 201, a GI removal unit 202, an FFT (Fast Fourier Transform) unit 203, a digital demodulation unit 204, a depuncture unit 205, an error correction decoding unit 206, and an error detection unit. 207, a feedback information generation unit 208, and a transmission RF unit 209.

  The reception RF unit 201 receives a signal transmitted from the transmission device 100 and performs predetermined reception processing (down-conversion, A / D conversion, etc.) on the received signal.

  GI removal section 202 removes the guard interval from the received signal, and outputs the signal after the guard interval removal to FFT section 203.

  The FFT unit 203 performs FFT processing on the signal after removal of the guard interval to obtain a systematic bit sequence and a parity bit sequence for each segment, and based on the segment information notified from the transmission device 100, The systematic bit sequence and the parity bit sequence of the segment are output to the digital demodulation unit 204.

  The digital demodulation unit 204 digitally demodulates the systematic bit sequence and the parity bit sequence for each segment, and outputs the demodulated systematic bit sequence and the parity bit sequence to the depuncture unit 205.

  Depuncturing section 205 performs depuncturing processing on the demodulated systematic bit sequence and parity bit sequence based on the coding rate information notified from transmitting apparatus 100, and outputs the result to error correction decoding section 206.

  Error correction decoding section 206 performs error correction decoding on the systematic bit sequence and parity bit sequence, and outputs received data.

  The error detection unit 207 performs error detection on the error correction decoding result of the error correction decoding unit 206 using an error detection code such as CRC, and notifies the feedback information generation unit 208 of the presence or absence of an error.

  The feedback information generation unit 208 generates feedback information for feedback to the transmission device 100. Specifically, feedback information generation section 208 generates propagation channel information indicating the delay spread and maximum Doppler frequency measured by a measurement section (not shown), and generates an ACK / NACK signal according to the presence or absence of an error.

  The transmission RF unit 209 transmits the feedback information generated by the feedback information generation unit 208 to the transmission device 100.

  Next, operations of the transmission device 100 and the reception device 200 configured as described above will be described with reference to FIGS. 3 and 4. Hereinafter, an operation after the ACK and the propagation channel information are fed back from the receiving apparatus 200 to the transmitting apparatus 100 will be described.

  The ACK and propagation channel information fed back from the receiving apparatus 200 are received by the reception RF unit 107 of the transmitting apparatus 100, and a predetermined reception process is performed. The received ACK and propagation channel information are output to ACK / NACK detection unit 108 and propagation channel information demodulation unit 109, ACK is detected by ACK / NACK detection unit 108, and propagation channel information is received by propagation channel information demodulation unit 109. Demodulated. When an ACK is detected by the ACK / NACK detection unit 108, the fact is notified to the segment allocation unit 112. The fact that the ACK / NACK signal is ACK means that the previously transmitted transmission data has been normally received by the receiving apparatus 200, and the transmitting apparatus 100 transmits new transmission data.

  Also, the propagation channel information obtained by the propagation channel information demodulation unit 109 is output to the coding rate determination unit 110 and the time / frequency correlation value calculation unit 111, and the coding rate determination unit 110 refers to the coding rate table. Thus, the coding rate is determined from the number of parity bits corresponding to the propagation channel information. That is, the coding rate for transmitting all the parity bits divided and transmitted in multiple times when normal HARQ is performed in the current propagation channel state by the coding rate determination unit 110 Is determined. Coding rate information indicating the determined coding rate is output to puncturing section 102.

  During this time, the transmission data is subjected to error correction coding by the error correction coding unit 101, and a systematic bit sequence and a parity bit sequence are generated. That is, for example, as shown in FIG. 3, an N-bit systematic bit sequence and an N-bit parity bit sequence (parity bit 1 and parity bit 2 in the figure) are generated from N-bit transmission data. The generated systematic bit sequence and parity bit sequence are subjected to puncturing processing based on the coding rate output from the coding rate determining unit 110 by the puncturing unit 102. The systematic bit sequence and parity bit sequence after puncturing are digitally modulated by the digital modulation unit 103 and output to the IFFT unit 104. The parity bit sequence here includes parity bits equal to the number of all parity bits transmitted from the initial transmission to the completion of retransmission when performing normal HARQ. That is, in normal HARQ, all the parity bits divided and transmitted in multiple times are transmitted at the time of initial transmission, and the number of retransmissions can be greatly reduced.

On the other hand, when the propagation channel information is output to the time / frequency correlation value calculation unit 111, the frequency interval B _seg for compensating the time diversity gain lost due to the decrease in the number of retransmissions by the time / frequency correlation value calculation unit 111 is described above. It is calculated | required from Formula (1)-(3). That is, first, the time correlation value ρ _t (RTT) of the propagation path characteristic corresponding to the time interval RTT between each transmission in the case of performing normal HARQ is obtained from the equation (1) by the time / frequency correlation value calculation unit 111. It is done. At this time, in normal HARQ, the time interval RTT also changes depending on the propagation environment, but the time / frequency correlation value calculation unit 111 determines the number of retransmissions and the time required for retransmission when the parameter included in the propagation channel information changes. Since the retransmission number table is held, an appropriate time interval RTT can be determined from the propagation channel information demodulated by the propagation channel information demodulator 109.

Then, the time / frequency correlation value calculation unit 111 obtains the frequency interval B _seg where the frequency correlation value ρ _f (B _seg ) expressed by the equation (2) satisfies the condition of the equation (3). That is, the frequency interval B _seg is calculated such that the frequency correlation value ρ _f (B _seg ) is equal to or less than the time correlation value ρ _t (RTT) when performing normal HARQ. At this time, the correlation between the propagation path characteristics at the frequency separated by the frequency interval B _seg is equivalent to the correlation between the propagation path characteristics between the transmissions when performing normal HARQ, and therefore, only the frequency separation B _{seg from} each other at the first transmission. A signal transmitted at a distant frequency will obtain a frequency diversity gain equivalent to the time diversity gain until the completion of retransmission in normal HARQ.

Further, the time / frequency correlation value calculation unit 111 calculates the number of segments x corresponding to the frequency interval B _seg by the equation (4), and notifies the segment allocation unit 112 of the calculated number of segments x.

Then, the segment allocation unit 112 determines the segment allocation so that systematic bit sequences and parity bit sequences addressed to the same receiving apparatus are arranged at intervals of the number of segments x or more. That is, a systematic bit sequence and a parity bit sequence addressed to the same receiving apparatus are allocated to segments at a segment interval based on the number of segments x shown in FIG. As a result, for example, as shown in FIG. 3, the systematic bit sequence and the parity bit sequence destined for the same receiving apparatus are allocated to segments separated from each other by a frequency interval B _seg or more. For this reason, the systematic bit sequence and the parity bit sequence addressed to the same receiving apparatus can obtain the frequency diversity gain, and can improve the reception quality. Segment information indicating the determined segment allocation is output to IFFT section 104. In addition, since the frequency diversity gain increases as the frequency interval of the segments to which the systematic bit sequence and the parity bit sequence are assigned increases, the frequency interval can be increased to reduce the number of parity bits.

Since the systematic bit sequence and the parity bit sequence are input to the IFFT unit 104, the systematic bit sequence and the parity bit sequence are assigned to each segment according to the segment information, and are subjected to IFFT processing to thereby generate a multicarrier. A signal is generated. This multicarrier signal includes all systematic bit sequences and parity bit sequences transmitted from the initial transmission to the completion of retransmission in the case of performing normal HARQ, and these bit sequences are separated from each other by a frequency interval B. It is superimposed on a segment with a frequency more than _seg .

  The generated multicarrier signal is inserted with a guard interval by the GI insertion unit 105, subjected to predetermined transmission processing by the transmission RF unit 106, and transmitted through the antenna together with the coding rate information and the segment information.

  The transmitted multicarrier signal is received by the reception RF unit 201 of the reception apparatus 200, and a predetermined reception process is performed. A guard interval is removed from the received signal by the GI removing unit 202, and FFT processing is performed by the FFT unit 203, whereby a systematic bit sequence and a parity bit sequence for each segment are acquired. Furthermore, the FFT unit 203 extracts from the segment information transmitted together with the multicarrier signal, a segment to which a systematic bit sequence and a parity bit sequence addressed to its own device are allocated, and the systematic bit sequence of the extracted segment and The parity bit sequence is output to the digital demodulator 204.

  Then, the digital demodulation section 204 performs digital demodulation, and the demodulated systematic bit series and parity bit series are output to the depuncture section 205. In the depuncture section 205, the coding rate information transmitted together with the multicarrier signal is used, and the demodulated systematic bit sequence and parity bit sequence are depunctured. The systematic bit sequence and the parity bit sequence after the depuncture processing are subjected to error correction decoding by the error correction decoding unit 206 and output received data, while the error detection unit 207 performs error detection of the error correction decoding result, The feedback information generation unit 208 is notified of the presence or absence.

  When the presence / absence of an error is output to feedback information generation section 208, feedback information generation section 208 generates ACK or NACK. That is, if there is no error, ACK is generated to transmit new data from transmitting apparatus 100, and if there is an error, NACK is generated from transmitting apparatus 100 to transmit a parity bit sequence for retransmission. Further, the feedback information generation unit 208 generates propagation channel information indicating the delay spread and the maximum Doppler frequency measured by a measurement unit (not shown), and the feedback information including the generated ACK / NACK signal and propagation channel information is: The signal is output to the transmission RF unit 209. The feedback information is subjected to a predetermined transmission process by the transmission RF unit 209 and transmitted to the transmission device 100 via the antenna.

  Hereinafter, when the feedback information is received by the transmitting apparatus 100 and the ACK / NACK signal included in the feedback information is ACK, the above-described transmission operation is repeated, and when it is NACK, the parity bit sequence for retransmission is any Assigned to the segment and transmitted.

  As described above, according to the present embodiment, a frequency interval that can compensate for time diversity gain when performing normal HARQ is calculated, and normal HARQ is performed on a segment having a frequency that is more than the calculated frequency interval. In this case, all systematic bit sequences and parity bit sequences transmitted from the initial transmission to the completion of retransmission are allocated and transmitted. In other words, when performing normal HARQ, all data transmitted divided into multiple times is transmitted at one time, and the decrease in time diversity gain due to the decrease in the number of transmissions is compensated by frequency diversity gain. Thus, reception quality can be improved while reducing the number of retransmissions.

  In the present embodiment, coding rate determining section 110 determines the coding rate from the number of parity bits associated with the propagation channel information, but coding rate determining section 110 The coding bit rate is calculated from the parity bit number n calculated by the following equation (5) using the forgetting count α (where 0 ≦ α ≦ 1). You may make it do.

n = α (number of parity bits used in previous transmission) + (1−α) (average value of number of parity bits used in previous transmission) (5)
Here, the forgetting factor α is set to be large when the maximum Doppler frequency is large and small when the maximum Doppler frequency is small. By doing so, it is possible to reflect the state of the propagation channel in determining the coding rate.

  In the present embodiment, all systematic bit sequences and parity bit sequences are transmitted only at the time of initial transmission, but may be divided and transmitted twice or more. Even in this case, the number of transmissions can be reduced as compared with normal HARQ. Then, since the time diversity gain is obtained by dividing the transmission into two or more times, the sum of the time diversity gain and the frequency diversity gain is set to be equal to or greater than the sum of the time diversity gains when performing normal HARQ. May be.

  The transmission apparatus according to the first aspect of the present invention is directed to an acquisition unit that acquires propagation channel information indicating an environment of a propagation channel between the reception apparatus and the reception apparatus at a coding rate according to the propagation channel information. Encoding means for encoding the transmission data, a calculating means for calculating a frequency interval according to the propagation channel information, and an assigning means for assigning the encoded transmission data to a segment of a frequency separated by the calculated frequency interval or more And a configuration having the following.

  According to this configuration, in order to transmit transmission data at a coding rate and frequency interval according to propagation channel information, all systematic bit sequences and parity that are divided and transmitted multiple times when performing normal HARQ In addition to transmitting the bit sequences collectively, a decrease in time diversity gain due to a decrease in the number of transmissions can be compensated by the frequency diversity gain, and reception quality can be improved while reducing the number of retransmissions.

  The transmitting apparatus according to a second aspect of the present invention is the transmission apparatus according to the first aspect, wherein the calculating means assumes a transmission time interval in the case of retransmitting transmission data by a hybrid automatic repeat request method based on the propagation channel information. Then, the time correlation value of the propagation path characteristic corresponding to the assumed transmission time interval is calculated, and the frequency interval at which the frequency correlation value of the propagation path characteristic is equal to or less than the time correlation value is adopted.

  According to this configuration, in order to calculate a frequency interval that becomes a frequency correlation value equal to or less than the time correlation value of the transmission time interval in the case of performing normal HARQ, the time diversity gain that is lost due to a decrease in the number of retransmissions is reduced to the frequency diversity gain. Can reliably compensate.

  The transmission apparatus according to a third aspect of the present invention is the transmission device according to the first aspect, wherein the encoding means propagates all the redundant bit numbers transmitted when transmitting transmission data by a hybrid automatic retransmission request method. An encoding rate determination unit that determines an encoding rate for transmitting the assumed number of redundant bits at the same time, based on channel information, and configured to encode transmission data at the determined encoding rate take.

  According to this configuration, when performing normal HARQ, since parity bits equal to the number of all the parity bits that are divided and transmitted multiple times are transmitted simultaneously, the number of retransmissions while maintaining error resistance by error correction coding Can be reduced.

  The transmission apparatus according to a fourth aspect of the present invention employs a configuration in which, in the first aspect, the acquisition unit acquires propagation channel information including at least delay spread and maximum Doppler frequency information.

  According to this configuration, since propagation channel information including at least delay spread and maximum Doppler frequency information is acquired, a time correlation value and a frequency correlation value of propagation path characteristics can be calculated, and a frequency at which frequency diversity gain can be obtained. The interval can be calculated accurately.

  A transmission method according to a fifth aspect of the present invention includes a step of obtaining propagation channel information indicating an environment of a propagation channel with a receiving device, and an address for the receiving device at a coding rate according to the propagation channel information. A step of encoding transmission data; a step of calculating a frequency interval according to the propagation channel information; and a step of allocating the encoded transmission data to a segment having a frequency separated by at least the calculated frequency interval. I made it.

  According to this method, since transmission data is transmitted at a coding rate and a frequency interval according to propagation channel information, all systematic bit sequences and parity that are divided and transmitted multiple times when performing normal HARQ. In addition to transmitting the bit sequences collectively, a decrease in time diversity gain due to a decrease in the number of transmissions can be compensated by the frequency diversity gain, and reception quality can be improved while reducing the number of retransmissions.

  The transmission apparatus and transmission method of the present invention can improve reception quality while reducing the number of retransmissions. For example, retransmission control is performed in accordance with an ACK / NACK signal fed back from the reception side, and a plurality of carriers having different frequencies are allocated. It is useful as a transmission apparatus and a transmission method for transmitting a multicarrier signal including the same.

The block diagram which shows the structure of the transmitter in one embodiment of this invention The block diagram which shows the structure of the receiver in one embodiment of this invention The figure which shows an example of segment allocation conversion in this invention The figure which shows an example of the mode of the segment allocation in this invention

Explanation of symbols

DESCRIPTION OF SYMBOLS 101 Error correction encoding part 102 Puncture part 103 Digital modulation part 104 IFFT part 105 GI insertion part 106 Transmission RF part 107 Reception RF part 108 ACK / NACK detection part 109 Propagation channel information demodulation part 110 Coding rate determination part 111 Time / frequency Correlation value calculation unit 112 Segment allocation unit

Claims (5)

Acquisition means for acquiring propagation channel information indicating the environment of the propagation channel with the receiving device;
Encoding means for encoding transmission data addressed to the receiving apparatus at a coding rate according to the propagation channel information;
Calculating means for calculating a frequency interval according to the propagation channel information;
Allocating means for allocating encoded transmission data to segments of frequencies separated by a calculated frequency interval;
A transmission device comprising: The calculating means includes
Based on the propagation channel information, a transmission time interval in the case where retransmission data is retransmitted by the hybrid automatic retransmission request method is calculated, a time correlation value of the propagation path characteristic corresponding to the assumed transmission time interval is calculated, and the propagation path characteristic The transmission apparatus according to claim 1, wherein a frequency interval at which a frequency correlation value is equal to or less than the time correlation value is calculated. The encoding means includes
When transmitting transmission data by the hybrid automatic repeat request method, all the redundant bit numbers to be transmitted are assumed based on the propagation channel information, and the coding rate for transmitting the assumed redundant bit number at the same time is determined. A coding rate determination unit,
The transmission apparatus according to claim 1, wherein the transmission data is encoded at the determined encoding rate. The acquisition means includes
The transmission apparatus according to claim 1, wherein propagation channel information including at least delay spread and maximum Doppler frequency information is acquired. Obtaining propagation channel information indicating the environment of the propagation channel with the receiving device;
Encoding transmission data addressed to the receiving device at a coding rate according to the propagation channel information;
Calculating a frequency interval according to the propagation channel information;
Assigning the encoded transmission data to segments of frequencies separated by at least the calculated frequency interval;
A transmission method characterized by comprising:

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