WO2015174053A1

WO2015174053A1 - Transmission method, reception method, transmission device, and reception device

Info

Publication number: WO2015174053A1
Application number: PCT/JP2015/002341
Authority: WO
Inventors: 村上　豊; 知弘木村; 幹博大内
Original assignee: パナソニックＩｐマネジメント株式会社
Priority date: 2014-05-16
Filing date: 2015-05-08
Publication date: 2015-11-19

Abstract

The present invention selects from a plurality of coding schemes one coding scheme per data symbol group, encodes an information sequence using the selected coding scheme, and obtains a coded sequence. The plurality of coding scheme include at least a first coding scheme and a second coding scheme. The first coding scheme uses a first parity-check matrix, uses a first generated codeword as a first coded sequence, and has a first coding rate. The second coding scheme uses a second parity-check matrix, generates a second coded sequence by puncturing a second generated codeword, and has a post-puncturing second coding rate. The bit number of the first coded sequence and the bit number of the second coded sequence are the same.

Description

Transmission method, reception method, transmission device, and reception device

The present disclosure relates to a broadcasting / communication system using an error correction code.

In broadcast / communication systems using wireless / wired, error correction codes are used to improve the reception quality of data at the receiving device. At this time, as the error correction code, it is desired to use an error correction code having a high correction capability in consideration of the operation scale. Under such circumstances, the use of LDPC (Low-Density-Parity-Check) codes is being studied in broadcasting / communication systems using wireless and wired communication. The block length (code length) and coding rate of the LDPC code are variable in consideration of the variable amount of data transmitted by the transmitter and the usage environment (reception in a mobile environment / reception in a semi-fixed environment). The system is being studied.

By the way, various studies have been made as a method for generating an LDPC code. For example, in Non-Patent Document 1, an information sequence is encoded using an LDPC code defined by a parity check matrix H1 (where N is the number of columns), and an N-bit codeword is generated and transmitted. It is described.

In Non-Patent Document 2, an information sequence is encoded using an LDPC code defined by a parity check matrix H2 (however, the number of columns is L and a relationship of N <L is established) and L bits are used. Codewords are generated. Then, it is described that, among L-bit codewords, LN non-transmitted bits are determined and the remaining N-bit sequence is transmitted (puncture method).

One aspect of the present disclosure is a transmission method using a plurality of encoding methods, wherein one encoding method is selected from a plurality of encoding methods for each data symbol group, and the selected encoding method is selected. An encoding step for encoding an information sequence to obtain an encoded sequence, a modulation step for modulating the encoded sequence to obtain a data symbol, and a transmission including a plurality of data symbol groups each including a plurality of data symbols A transmission method including transmitting a frame. The plurality of encoding schemes include at least a first encoding scheme and a second encoding scheme. The first coding scheme is a first coding rate coding scheme that uses a first parity check matrix and uses the generated first codeword as a first coded sequence. The second encoding method uses a second parity check matrix different from the first parity check matrix and performs a puncture process on the generated second codeword, thereby obtaining a second encoded sequence. This is a coding method of the second coding rate after puncture processing that is different from the first coding rate to be generated. The number of bits of the first encoded sequence is equal to the number of bits of the second encoded sequence.

FIG. 1 is a diagram illustrating an example of a configuration of a reception device and a transmission device using radio. FIG. 2 is a diagram illustrating an example of the configuration of the encoder. FIG. 3 is a diagram illustrating an example of the operation of the transmission device when puncturing is used. FIG. 4 is a diagram illustrating an example of the operation of the reception device when puncturing is used. FIG. 5 is a diagram illustrating an example of an encoding method selected for a code length and an encoding rate. FIG. 6 is a diagram illustrating an example of a coding method selected for a code length and a coding rate. FIG. 7 is a diagram illustrating an example of a coding method selected for a code length and a coding rate. FIG. 8 is a diagram illustrating an example of a coding method selected for a code length and a coding rate. FIG. 9 is a diagram illustrating an example of an encoding method selected for a code length. FIG. 10 is a diagram illustrating an example of an encoding method selected for a code length. FIG. 11 is a diagram illustrating an example of a configuration of a frame transmitted by the transmission apparatus. FIG. 12 is a diagram illustrating an example of an encoding method selected for an encoding rate. FIG. 13 is a diagram illustrating an example of an encoding method selected for an encoding rate. FIG. 14 is a diagram illustrating an example of an encoding method selected for an encoding rate. FIG. 15 is a diagram illustrating an example of a coding method selected for a code length and a coding rate. FIG. 16 is a diagram illustrating an example of a coding method selected for a code length and a coding rate. FIG. 17 is a diagram illustrating an example of the configuration of the transmission apparatus. FIG. 18 is a diagram illustrating an example of a frame configuration of a modulation signal transmitted by the transmission apparatus. FIG. 19 is a diagram illustrating an example of a configuration of parts related to the control information demodulating unit and the decoding unit. FIG. 20 is a diagram illustrating an example of a frame configuration of a modulation signal transmitted by the transmission apparatus.

The present disclosure relates to an LDPC code used in a system for a receiver to obtain higher data reception quality in a broadcasting / communication system using wireless / wired with variable block length (code length) and coding rate. Related to the setting.

One aspect of the present disclosure is a reception method that uses a plurality of decoding methods, and includes a demodulation step that demodulates a received signal, and a decoding step that performs error correction decoding on a plurality of reception values generated by the demodulation. Including a receiving method. The received signal includes a plurality of data symbol groups including a plurality of data symbols to form a frame, and the data symbols are encoded by switching the encoding method in units of data symbol groups. When a plurality of received values are encoded by the first encoding method, the first decoding method corresponding to the first encoding method is applied to the plurality of received values. In addition, when a plurality of received values are encoded by the second encoding method, the depuncture process is applied to the plurality of received values, and the second value is applied to the plurality of values after the depuncture process. The second decoding method corresponding to the encoding method is applied. The first coding scheme is a first coding rate coding scheme that uses a first parity check matrix and uses the generated first codeword as a first coded sequence. The second encoding method uses a second parity check matrix different from the first parity check matrix and performs a puncture process on the generated second codeword, thereby obtaining a second encoded sequence. This is a coding method of the second coding rate after puncture processing that is different from the first coding rate to be generated. The number of bits of the first encoded sequence is equal to the number of bits of the second encoded sequence.

One aspect of the present disclosure is a transmission apparatus that uses a plurality of encoding schemes, and selects one encoding scheme from a plurality of encoding schemes for each data symbol group, and selects the selected encoding scheme. A transmission unit configured to encode an information sequence to obtain an encoded sequence, a modulation unit to modulate the encoded sequence to obtain a data symbol, and a plurality of data symbol groups including a plurality of data symbols A transmission unit that transmits the frame. The plurality of encoding schemes include at least a first encoding scheme and a second encoding scheme. The first coding scheme is a first coding rate coding scheme that uses a first parity check matrix and uses the generated first codeword as a first coded sequence. The second encoding method uses a second parity check matrix different from the first parity check matrix and performs a puncture process on the generated second codeword, thereby obtaining a second encoded sequence. This is a coding method of the second coding rate after puncture processing that is different from the first coding rate to be generated. The number of bits of the first encoded sequence is equal to the number of bits of the second encoded sequence.

One aspect of the present disclosure is a reception device that uses a plurality of decoding methods, a demodulation unit that demodulates a reception signal, a decoding unit that performs error correction decoding on a plurality of reception values generated by the demodulation unit, Is provided. The received signal includes a plurality of data symbol groups including a plurality of data symbols to form a frame, and the data symbols are encoded by switching the encoding method in units of data symbol groups. When a plurality of received values are encoded by the first encoding method, the decoding unit applies a first decoding method corresponding to the first encoding method to the plurality of received values. Apply. In addition, when a plurality of received values are encoded by the second encoding method, the decoding unit applies a depuncture process to the plurality of received values, and converts the plurality of received values into a plurality of values after the depuncture process. On the other hand, the second decoding method corresponding to the second encoding method is applied. The first coding scheme is a first coding rate coding scheme that uses a first parity check matrix and uses the generated first codeword as a first coded sequence. The second encoding method uses a second parity check matrix different from the first parity check matrix and performs a puncture process on the generated second codeword, thereby obtaining a second encoded sequence. This is a coding method of the second coding rate after puncture processing that is different from the first coding rate to be generated. The number of bits of the first encoded sequence is equal to the number of bits of the second encoded sequence.

FIG. 1 shows an example of a configuration of a system using radio, which includes a transmission device 100 and a reception device 150. In FIG. 1, a system using wireless is used, but the system is not limited to this, and a system using wired (coaxial cable, cable, light, etc.) may be used.

Encoding section 103 receives information 101 and control information 102 as input, and information on codes used by the transmission apparatus included in control information 102 for error correction encoding, for example, information on coding rate and code length (block length). Is performed, and the data 104 after error correction coding is output.

Puncturing section 105 receives control information 102 and data 104 after error correction coding as input, and information on codes used for error correction coding by the transmission device included in control information 102, for example, coding rate, code length ( Based on the block length) information, it is determined whether the data 104 after error correction coding is to be punctured or not (a part of the bit sequence is deleted), and the data 106 is output. To do.

Interleaving section 107 receives control information 102 and data 106 as input, rearranges data based on information on the interleaving method included in control information 102, and outputs rearranged data 108.

The mapping unit 109 receives the control information 102 and the rearranged data 108 as input, performs mapping based on information on the modulation method included in the control information 102, and outputs a baseband signal 110.

Radio section 112 receives control information 102, baseband signal 110, and pilot signal 111 as input, and includes a control information symbol (including information on modulation scheme, error correction code scheme, etc.) for the receiver to demodulate from control information 102 And processing such as inserting pilot symbols into data symbols, generating frames, and performing signal processing based on control information 102 (for example, when using OFDM (Orthogonal Frequency Division Multiplexing) Signal processing based on space-time code or MIMO (Multiple Input-Multiple-Output) method, signal processing based on that, frequency conversion, band limitation, amplification, etc. are performed), and transmission signal 113 is output The transmission signal 113 is output as a radio wave from the antenna 114 (note that the number of antennas is two) But not limited to this).

1 in FIG. 1 shows an example of the configuration of a receiving apparatus that receives a modulated signal transmitted by the transmitting apparatus 100.

The wireless unit 153 performs processing such as reception signal 152 received by the antenna 151 and frequency conversion, and outputs a baseband signal 154.

Synchronization section 155 receives baseband signal 154 as input, performs processing for frequency synchronization and time synchronization using pilot symbols, preambles, and the like included in the baseband signal, and outputs synchronization signal 156.

Channel estimation section 157 receives baseband signal 154 as input, performs channel estimation using pilot symbols, preambles, etc. included in the baseband signal, and outputs channel estimation signal 15.

Control information demodulation section 159 receives baseband signal 154 as input, demodulates control information symbols included in the baseband signal, and outputs control information signal 160.

The demodulator 161 receives the baseband signal 154, the synchronization signal 156, the channel estimation signal 158, and the control information signal 160, and based on the information related to the transmission method such as the modulation method included in the control information signal 160, the demodulation signal 156, the channel For example, a log likelihood ratio of each bit of the data symbols included in the baseband signal 154 is obtained using the estimated signal 158, and a log likelihood ratio signal 162 is output.

Deinterleaving section 163 receives control information signal 160 and log-likelihood ratio signal 162 as input, rearranges the order of log-likelihood ratios based on the information related to the interleaving method included in control information signal 160, and after the rearrangement Log likelihood ratio signal 164 is output.

Insertion section 165 receives control information signal 160 as input, and whether or not the transmission apparatus has punctured based on block length (code length) and coding rate information of the error correction code in control information signal 160 ( It is determined whether a part of the bit sequence has been deleted or not.

When the insertion unit 165 determines that “the transmission device has punctured”, the log likelihood ratio corresponding to the bit that has been punctured (deleted) by the transmission device with respect to the log likelihood ratio signal 164 after the rearrangement. (For example, the value is “0”).

When the insertion unit 165 determines that “the transmission apparatus is not puncturing”, the log likelihood ratio is not inserted.

Then, the insertion unit 165 outputs the second log likelihood ratio signal 166.

Decoding section 167 receives control information signal 160 and second log-likelihood ratio signal 166 as input, performs error correction decoding based on information related to the error correction code included in the control information signal, and outputs received data 168. In this disclosure, since LDPC codes are handled, reliability propagation (BP: belief propagation) decoding (for example, sum-product decoding, min-sum decoding, Laired BP decoding, etc.) is performed based on a parity check matrix. Will be done.

The LDPC code will be described. FIG. 2 shows the configuration of the encoder.
An information sequence u = (x ₁ , x ₂ ,..., X _m ) (201), and an encoded sequence s = (x ₁ , x ₂ ,..., X _m , p ₁ , p ₂ ,..., P _n ) ( 203), and the parity check matrix is H, the following equation holds. (M is a natural number and n is a natural number).
Hs ^T = 0
Using the relationship of the above equation, the encoder 202 receives the information sequence u = (x ₁ , x ₂ ,..., X _m ) and inputs the encoded sequence s = (x ₁ , x ₂ ,..., X _m , P ₁ , p ₂ ,..., _Pn ) are generated and output. The encoding rate R = m / (m + n). Note that (p ₁ , p ₂ ,..., P _n ) is called a parity sequence.

Therefore, the transmission apparatus transmits a total of m + n bits of (x ₁ , x ₂ ,..., X _m , p ₁ , p ₂ ,..., P _n ) as one encoded block.

At this time, the number of rows of the parity check matrix H is n and the number of columns is m + n.

Here, the case of performing the encoding as shown in FIG. 2 is referred to as “LDPC encoding method without puncturing”.

Next, an LDPC code using puncture will be described.

In the LDPC code described above, in the transmission apparatus, y bits that are not transmitted are determined in the encoded sequence s = (x ₁ , x ₂ ,..., X _m , p ₁ , p ₂ ,..., P _n ). Then, the transmitting apparatus transmits a sequence of m + ny bits other than the determined bits. A specific example of an LDPC code using puncture is shown in FIG.

In FIG. 3, for example, a total of y bits “x ₃ ,..., X _m−2 , p ₁ ,..., P _n−1 ” is selected, and the transmission apparatus determines that these y bits are not transmitted. A sequence of m + ny bits other than the bits determined not to be transmitted is transmitted as z ₁ , z ₂ , z ₃ ,..., Z _{m + ny + 2} , z _{m + ny + 1} , z _{m + ny} .

In the example of FIG. 3, the y bits not to be transmitted are selected from both the information sequence and the parity sequence. However, the present invention is not limited to this, and it may be selected only from the information sequence, or only the parity sequence. You may choose from. That is, the y bits not to be transmitted may be selected in any way from the encoded sequence.

Therefore, the transmission apparatus transmits a total of m + ny bits of (z ₁ , z ₂ , z ₃ ,..., Z _{m + ny−2} , z _{m + ny−1} , z _{m + ny} ) as one encoded block. .

Here, the above-described method is referred to as “LDPC encoding method using puncture”.

FIG. 4 shows an example of an operation example of the receiving apparatus when the transmitting apparatus transmits data as shown in FIG.

The sequence z ₁ , z ₂ , z ₃ ,..., Z _{m + n−y + 2} , z _{m + n−y + 1} , z _{m +} ny is received by the receiver, and the log likelihood ratio of these bits is _expressed as Lz ₁ , Lz ₂ , Lz _3. ,..., Lz _{m +} ny ₋₂ , Lz _{m +} ny _{+ 1} , and Lz _{m +} ny.

As shown in FIG. 4, the receiver, the bit transmission device did not send _{_{_{"x 3, ..., x m-}}} 2, p 1, ..., p n-1 " a total of y for each bit of bit log-likelihood For example, the degree ratio is set to “0 (zero)”. Therefore, “log likelihood ratio of x ₃ =..., Log likelihood ratio of x _m−2 = 0, log likelihood ratio of p ₁ = 0..., Log likelihood ratio of p _n−1 = 0” Insert. _{_{_{_{Thus, x 1, x 2, x}}}} 3, ..., x m-2, x m-1, x m, p 1, p 2, p 3, ..., of _{p n-2, p n-} 1, p n log-likelihood ratio _Lx 1 of each _{_{_{_{bit, Lx 2, Lx 3, ...}}}} , Lx m-2, Lx m-1, Lx m, Lp 1, Lp 2, Lp 3, ..., Lp n-2, Lp n- _1, Lp _n is obtained. Then, the receiving _{_{_{_{apparatus, Lx 1, Lx 2, Lx}}}} 3, ..., Lx m-2, Lx m-1, Lx m, Lp 1, Lp 2, Lp 3, ..., Lp n-2, Lp n-1 , using the Lp _n, performs BP decoding, thereby obtaining reception data.

Next, consider a case where the transmission apparatus supports α bits and β bits as the number of bits of one encoded block for the coding rate R = γ. Note that α and β are natural numbers, and α <β holds.

In the case of “LDPC coding method using puncture”, code rate (block length) α + v bits (where v is a natural number), coding rate q for coding rate R = γ and 1 coding block α bit. However, an LDPC code of q <γ is used, and then puncturing is performed. This method is named “method # 1”.

Similarly, in the case of “LDPC encoding method using puncture”, code length (block length) β + u bits (where u is a natural number), code for coding rate R = γ and 1 encoded block β bits An LDPC code having a conversion rate q (where q <γ) is used. After that, puncture is performed. This method is named “method # 2”.

On the other hand, in the case of the “LDPC coding method without puncturing”, an LDPC code having a code length (block length) α bits and a coding rate γ for coding rate R = γ and 1 coding block α bits. Will be used. This method is referred to as “method # 3”.

Similarly, in the case of the “LDPC encoding method without puncturing”, an LDPC code having a code length (block length) β bits and an encoding rate γ for an encoding rate R = γ and 1 encoding block β bits. Will be used. This method is referred to as “method # 4”.

Investigate under the condition that the relationship of α <β holds.

At this time, when the number of bits of one encoded block is α bits, “method # 1” may give higher data reception quality than “method # 3”.

On the other hand, when the number of bits of one encoded block is β, “method # 4” may give higher data reception quality than “method # 2”.

The reason is described below.

In order to realize the bit number α bit of one encoded block, in the case of “method # 1,” an α + v bit LDPC code having a code length (block length) larger than α is used. Here, when α <β and α is small, the contribution of the added v value in the code length (block length) α + v bits is large, so an LDPC code having a code length (block length) α bits was used. There are cases where higher data reception quality can be obtained when “method # 1” is used than when the method is used.

On the other hand, in order to realize the number of bits β of one encoded block, in the case of “method 2”, a β + u-bit LDPC code having a code length (block length) larger than β is used. Here, when α <β and β is large, the contribution of the added u value in the code length (block length) β + u bits is small, and deterioration due to puncturing is large. Therefore, when an LDPC code having a code length (block length) β bits is used, that is, “method # 4” may give higher data reception quality than “method 2”.

However, it depends on the specific values of α and β. (Also, the values of α and β may vary depending on the coding rate.) Specific examples will be shown below.

FIG. 5 is an example showing which one of “method #A” and “method #B” is used for the number of bits z and the coding rate of one encoded block. In the case of “method #A”, the coding rate means not the coding rate of the LDPC code but the coding rate after puncturing (after deleting the bits not to be transmitted).

In the example of FIG. 5, when one encoded block z = 8100 bits, the encoding rate is 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12 / Both 15, 13/15 are realized by “method #A”.

When one encoded block z = 1,200 bits, the encoding rate is 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12/15, 13 /. 15 is realized by “method #A”.

When 1 coding block z = 64800 bits, any of coding rates 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12/15, 13/15 Is also realized by “method #B”.

At this time, when the number of bits of one encoded block is a certain value, “method #A at coding rate a” “method #A at coding rate b” (provided that a ≠ b). think of. (However, it is assumed that both the coding rate a and the coding rate b are coding rates after puncturing (after deleting non-transmitted bits).) At this time, a and b satisfying at least one of the following conditions: Shall exist.

Condition 5-1: The LDPC code that is the basis of “method #A at coding rate a” and the LDPC code that is the basis of “method #A at coding rate b” are different codes.

Condition 5-2: The parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the parity of the LDPC code that is the basis of “method #A at coding rate b” The check matrix is different.

Condition 5-3: The number of rows of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of rows of the parity check matrix of the code is different.

Condition 5-4: The number of columns of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of columns of the code parity check matrix is different.

Suppose that the number of bits of one encoded block is z bits. Z is a natural number.

利用 Realize 1 encoded block z bit using “LDPC encoding method using puncture”. This method is referred to as “method #A”.

利用 Realize 1 encoded block z bit using “LDPC encoding method without puncturing”. This method is referred to as “method #B”.

The transmission device and the reception device set the coding rate from the coding rates as shown in FIG. 6, and select one coding block from the number of bits of one coding block as shown in FIG. And

FIG. 6 is an example showing which one of “method #A” and “method #B” is used for the number of bits z and the coding rate of one encoded block. In the case of “method #A”, the coding rate means not the coding rate of the LDPC code but the coding rate after puncturing (after deleting the bits not to be transmitted).

In the example of FIG. 6, when one encoded block z = 8100 bits, the coding rate is 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12 /. Both 15, 13/15 are realized by “method #A”.

When one encoded block z = 1,200 bits, the encoding rate is 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12/15, 13 /. 15 is realized by “method #B”.

Condition 6-1: The LDPC code that is the basis of “method #A at coding rate a” and the LDPC code that is the basis of “method #A at coding rate b” are different codes.

Condition 6-2: The parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the parity of the LDPC code that is the basis of “method #A at coding rate b” The check matrix is different.

Condition 6-3: The number of rows of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of rows of the parity check matrix of the code is different.

Condition 6-4: The number of columns of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of columns of the code parity check matrix is different.

The transmission device and the reception device set the coding rate from the coding rates as shown in FIG. 7, and select one coding block from the number of bits of one coding block as shown in FIG. And

FIG. 7 is an example showing which one of “method #A” and “method #B” is used for the number of bits z and the coding rate of one encoded block. In the case of “method #A”, the coding rate means not the coding rate of the LDPC code but the coding rate after puncturing (after deleting the bits not to be transmitted).

In the example of FIG. 7, when one encoded block z is 1000 bits or more and 9000 bits or less, the coding rate is 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11 /. Both 15, 12/15, and 13/15 are realized by “method #A”.

When one encoded block z is 10,000 bits or more and 20000 bits or less, the coding rate is 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12 / Both 15, 13/15 are realized by “method #A”.

When one encoded block z is 50000 bits or more and 70000 bits or less, the coding rate is 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12/15, Both of 13/15 are realized by “method #B”.

Condition 7-1: The LDPC code that is the basis of “method #A at coding rate a” and the LDPC code that is the basis of “method #A at coding rate b” are different codes.

Condition 7-2: Parity check matrix of LDPC code that is the basis of “method #A at coding rate a” and parity of LDPC code that is the basis of “method #A at coding rate b” The check matrix is different.

Condition 7-3: The number of rows of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of rows of the parity check matrix of the code is different.

Condition 7-4: The number of parity check matrix columns of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of columns of the code parity check matrix is different.

The transmission device and the reception device set a coding rate from the coding rates as shown in FIG. 8, and select one coding block from the number of bits of one coding block as shown in FIG. And

FIG. 8 is an example showing which one of “method #A” and “method #B” is used for the number of bits z and the coding rate of one encoded block. In the case of “method #A”, the coding rate means not the coding rate of the LDPC code but the coding rate after puncturing (after deleting the bits not to be transmitted).

In the example of FIG. 8, when one encoded block z is 1000 bits or more and 9000 bits or less, the coding rate is 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11 /. Both 15, 12/15, and 13/15 are realized by “method #A”.

When one encoded block z is 10,000 bits or more and 20000 bits or less, the coding rate is 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12 / Both 15, 13/15 are realized by “method #B”.

Condition 8-1: The LDPC code that is the basis of “method #A at coding rate a” and the LDPC code that is the basis of “method #A at coding rate b” are different codes.

Condition 8-2: Parity check matrix of LDPC code based on “method #A at coding rate a” and parity of LDPC code based on “method #A at coding rate b” The check matrix is different.

Condition 8-3: The number of rows of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of rows of the parity check matrix of the code is different.

Condition 8-4: The number of columns of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of columns of the code parity check matrix is different.

Suppose that the transmission device and the reception device select one encoded block from the number of bits of one encoded block as shown in FIG. Note that the coding rate can also be set.

FIG. 9 is an example showing which one of “method #A” and “method #B” is used for the number of bits z of one encoded block. In the case of “method #A”, the coding rate means not the coding rate of the LDPC code but the coding rate after puncturing (after deleting the bits not to be transmitted).

In the example of FIG. 9, when one encoded block z is less than 20000 bits, “method #A” is used.

Then, when one encoded block z is 20000 bits or more, “method #B” is used.

Condition 9-1: The LDPC code that is the basis of “method #A at coding rate a” and the LDPC code that is the basis of “method #A at coding rate b” are different codes.

Condition 9-2: Parity check matrix of LDPC code that is the basis of “method #A at coding rate a” and parity of LDPC code that is the basis of “method #A at coding rate b” The check matrix is different.

Condition 9-3: The number of rows of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of rows of the parity check matrix of the code is different.

Condition 9-4: The number of parity check matrix columns of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of columns of the code parity check matrix is different.

FIG. 10 is an example showing which one of “method #A” and “method #B” is used for the number of bits z of one encoded block. In the case of “method #A”, the coding rate means not the coding rate of the LDPC code but the coding rate after puncturing (after deleting the bits not to be transmitted).

In the example of FIG. 10, when one encoded block z is less than 10,000 bits, “method #A” is used.

Then, when one encoded block z is 10,000 bits or more, “method #B” is used.

Condition 10-1: The LDPC code that is the basis of “method #A at coding rate a” and the LDPC code that is the basis of “method #A at coding rate b” are different codes.

Condition 10-2: The parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the parity of the LDPC code that is the basis of “method #A at coding rate b” The check matrix is different.

Condition 10-3: The number of rows of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of rows of the parity check matrix of the code is different.

Condition 10-4: The number of columns of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of columns of the code parity check matrix is different.

FIG. 11 is an example of the configuration of a frame transmitted by the transmission apparatus, and the horizontal axis is time. In FIG. 11, for example, a transmission method using a single carrier is used as an example. However, when a multi-carrier scheme such as OFDM (Orthogonal Frequency Division Multiplexing) is used, there are a plurality of carriers in the frequency direction. There will be a symbol in the carrier direction. For example, when a space-time code or a MIMO (Multiple-Input-Multiple-Output) method is used, a frame exists for each stream.

In FIG. 11, reference numeral 1101 denotes a preamble, which uses, for example, a known PSK (Phase Shift Keying) modulation symbol between the transceivers. The receiver uses this symbol to perform frequency offset estimation, frequency synchronization, time synchronization, frame synchronization, symbol synchronization, channel estimation, signal detection, and the like.

1102 is a control information symbol, for example, used to generate error correction code scheme (code length, block length of one encoded block, coding rate) information and data symbol used to generate a data symbol. Information on the modulation method, information on the transmission method, and the like. The receiving apparatus demodulates the symbol to obtain control information, thereby enabling data symbol demodulation and error correction decoding.

Further, based on the information obtained from the control information symbol 1102, whether or not to insert the log likelihood ratio described with reference to FIG. 1 is controlled.

Reference numeral 1103 denotes a data symbol, which is generated based on the error correction code scheme (code length, block length of one encoded block, coding rate) selected by the transmission apparatus, modulation scheme, and transmission method. Become. Although not described in FIG. 11, symbols such as pilot symbols may be inserted into the control information symbol 1102 and the data symbol 1103.

Therefore, the frame configuration is not limited to the configuration of FIG.

The transmission apparatus can select a value of one encoded block of data to be transmitted from a plurality of values, and provides a threshold value. When one encoded block of data transmitted by the transmission apparatus is equal to or greater than the threshold value, The transmission apparatus selects the “LDPC encoding method not to be performed”. When the transmission apparatus is less than the threshold value, the “LDPC encoding method using puncture” is selected and the data is transmitted so that the reception apparatus Even in the block value, it is possible to obtain an effect that high data reception quality can be obtained.

Next, consider a case where the transmission apparatus supports coding rates α, β, and γ for the number of bits δ of one encoded block. Note that α, β, and γ are values larger than 0 and smaller than 1, and α <β <γ holds. Note that the coding rate in the case of the “LDPC coding method using puncturing” means the coding rate after puncturing (after deleting bits that are not transmitted).

In the case of “LDPC encoding method using puncture”, code rate (block length) δ + u bits (where u is a natural number), code rate a for code rate R = α and 1 code block δ bits. However, an LDPC code of a <α is used, and then puncturing is performed. This method is named “method $ 1”.

Similarly, in the case of “LDPC encoding method using puncture”, code length (block length) δ + v bits (where v is a natural number), code for coding rate R = β and 1 encoded block δ bits An LDPC code having a conversion rate b (where b <β) is used, and then puncturing is performed. This method is named “method $ 2”.

In the case of “LDPC encoding method using puncture”, code rate (block length) δ + w bits (where w is a natural number), code rate c for code rate R = γ and 1 code block δ bits. However, an LDPC code of c <γ is used, and then puncturing is performed. This method is named “method $ 3”.

On the other hand, in the case of the “LDPC coding method without puncturing”, an LDPC code having a code length (block length) δ bits and a coding rate α for coding rate R = α and 1 coding block δ bits. Will be used. This method is named “method $ 4”.

Similarly, in the case of the “LDPC coding method without puncturing”, an LDPC code having a code length (block length) δ bits and a coding rate β is used for coding rate R = β and 1 coding block δ bits. Will be used. This method is named “method $ 5”.

In the case of “LDPC encoding method without puncturing”, an LDPC code having a code length (block length) δ bits and a coding rate γ is used for coding rate R = γ and 1 coding block δ bits. Become. This method is named “method $ 6”.

Consideration is made under the condition that α <β <γ holds.

At this time, when the coding rate is as small as α, “method $ 4” may give higher data reception quality than “method $ 1”.

When the coding rate is an intermediate value such as β, “method $ 2” may give higher data reception quality than “method $ 5”.

When the coding rate is as large as γ, “method $ 6” may give higher data reception quality than “method $ 3”.

The reason is described below.

The performance of LDPC codes with low coding rates tends to increase the difference from the Shannon limit. Therefore, in the case of a small (low) coding rate like the coding rate α, the coding rate of the base LDPC code is smaller than α at the time of “method $ 1,” and thus the difference from the Shannon limit is large. When puncturing, it is difficult to obtain good data reception quality.

In the case of an intermediate coding rate such as coding rate β, the difference between the Shannon limit of the coding rate of the base LDPC code and the Shannon limit of the coding rate after puncturing is large in “method $ 2.” Therefore, the performance of the base LDPC code contributes, and “method $ 2” has a high possibility of giving high data reception quality.

When the coding rate is as high as the coding rate γ, the difference between the Shannon limit of the coding rate of the base LDPC code and the Shannon limit of the coding rate after puncturing is small in “method $ 3”. For this reason, it may be difficult for “method $ 3” to obtain high data reception quality. However, “method $ 3” has an advantage that a sparse parity check matrix can be used as compared with “method $ 6”, and thus “method $ 3” may give good reception quality.

However, it depends on the specific values of α, β and γ. (Also, the values of α, β, and γ may vary depending on the value of one encoded block.) A specific example is shown below.

Suppose that the transmission device and the reception device select a coding rate from a coding rate as shown in FIG. It is assumed that the number of bits of one encoded block can also be set.

FIG. 12 is an example showing which one of “method #A” and “method #B” is used when the number of bits z of one encoded block is set to a certain value. In the case of “method #A”, the coding rate means not the coding rate of the LDPC code but the coding rate after puncturing (after deleting the bits not to be transmitted).

In FIG. 12, it is assumed that e and f are larger than 0 and smaller than 1, and e <f is established.

In the example of FIG. 12, “method #B” is used when the coding rate is less than f in the case of one coding block z (z is a natural number).

Then, when one coding block z (z is a natural number), when the coding rate is e or more and f or less, “method #A” is used.

Then, when one coding block z (z is a natural number) and the coding rate is larger than f, “method #B” is used.

There are a and b satisfying the coding rate e and below f, and the transmission apparatus can select “method #A when the coding rate is a” and “method #A when the coding rate is b”. Shall. (However, it is assumed that both the coding rate a and the coding rate b are coding rates after puncturing (after deleting non-transmitted bits)) (where a ≠ b).

At this time, it is assumed that a and b satisfy at least one of the following conditions.

Condition 12-1: The LDPC code that is the basis of “method #A at coding rate a” and the LDPC code that is the basis of “method #A at coding rate b” are different codes.

Condition 12-2: Parity check matrix of LDPC code that is the basis of “method #A at coding rate a” and the parity of LDPC code that is the basis of “method #A at coding rate b” The check matrix is different.

Condition 12-3: The number of rows of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of rows of the parity check matrix of the code is different.

Condition 12-4: The number of columns of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of columns of the code parity check matrix is different.

As described above, it is assumed that “the number of bits z of one encoded block is set to a certain value”.

Therefore, the coding rate is less than f, the coding rate is one or more types, the coding rate is e or more, the coding rate is less than f, the coding rate is two or more types, and the coding rate is larger than f. .

FIG. 13 is an example showing which one of “method #A” and “method #B” is used for the number of bits z of one encoded block. In the case of “method #A”, the coding rate means not the coding rate of the LDPC code but the coding rate after puncturing (after deleting the bits not to be transmitted).

In FIG. 13, g is assumed to be larger than 0 and smaller than 1.

In the example of FIG. 13, when one coding block z (z is a natural number) and the coding rate is less than g, “method #B” is used.

Then, in the case of one coding block z (z is a natural number), when the coding rate is g or more, “method #A” is used.

A and b satisfying the coding rate g or more exist, and the transmission apparatus can select “method #A when the coding rate is a” and “method #A when the coding rate is b”. To do. (However, it is assumed that both the coding rate a and the coding rate b are coding rates after puncturing (after deleting bits that are not transmitted).) (However, a ≠ b) At this time, It is assumed that a and b satisfy at least one of the above conditions.

Condition 13-1: The LDPC code that is the basis of “method #A at coding rate a” and the LDPC code that is the basis of “method #A at coding rate b” are different codes.

Condition 13-2: Parity check matrix of LDPC code that is the basis of “method #A at coding rate a” and parity of LDPC code that is the basis of “method #A at coding rate b” The check matrix is different.

Condition 13-3: The number of rows of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of rows of the parity check matrix of the code is different.

Condition 13-4: The number of parity check matrix columns of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of columns of the code parity check matrix is different.

Therefore, it is preferable that there are one or more coding rates with a coding rate less than g and two or more coding rates with a coding rate of g or more.

FIG. 14 is an example showing which one of “method #A” and “method #B” is used for the number of bits z of one encoded block. In the case of “method #A”, the coding rate means not the coding rate of the LDPC code but the coding rate after puncturing (after deleting the bits not to be transmitted).

In FIG. 14, h is greater than 0 and less than 1.

In the example of FIG. 14, when one coding block z (z is a natural number) and the coding rate is less than h, “method #A” is used.

And, in the case of one coding block z (z is a natural number), when the coding rate is h or more, “method #B” is used.

A and b satisfying less than the coding rate h exist, and the transmission apparatus can select “method #A when the coding rate is a” and “method #A when the coding rate is b”. To do. (However, it is assumed that both the coding rate a and the coding rate b are coding rates after puncturing (after deleting bits that are not transmitted).) (However, a ≠ b) At this time, It is assumed that a and b satisfy at least one of the above conditions.

Condition 14-1: The LDPC code that is the basis of “method #A at coding rate a” and the LDPC code that is the basis of “method #A at coding rate b” are different codes.

Condition 14-2: Parity check matrix of LDPC code that is the basis of “method #A when coding rate is a” and parity of LDPC code that is the basis of “method #A when it is coding rate b” The check matrix is different.

Condition 14-3: The number of rows of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of rows of the parity check matrix of the code is different.

Condition 14-4: The number of columns of the parity check matrix of the LDPC code that is the basis of “method #A at coding rate a” and the LDPC that is the basis of “method #A at coding rate b” The number of columns of the code parity check matrix is different.

Therefore, it is preferable that there are two or more types of coding rates with a coding rate of less than h and one or more types of coding rates with a coding rate of h or more.

The operation of the transmitting device and the receiving device is as described above with reference to FIGS.

The transmission apparatus sets the value of one encoded block of data to be transmitted to a predetermined value, sets a threshold value, and selects the “LDPC encoding method that does not perform puncturing” when the transmission apparatus has a coding rate equal to or higher than the threshold value, When the coding rate is less than the threshold, select “LDPC coding method using puncture”,
Or
When the coding rate is equal to or higher than the threshold, select “LDPC coding method using puncture”, and when the coding rate is less than the threshold, select “LDPC coding method without puncturing”. The apparatus can obtain an effect that high data reception quality can be obtained at any coding rate.

(Embodiment A)
In the present embodiment, an example of the configuration of the control information transmission method, the transmission device, the reception method, and the reception device in the embodiments described above will be described.

FIG. 15 is an example of parameters of the error correction code in the present embodiment. The number of bits of one encoded block is z bits. Z is a natural number.

利用 Realize 1 encoded block z bit using “LDPC encoding method using puncture”. This method is named “method #A”.

利用 Realize 1 encoded block z bit using “LDPC encoding method without puncturing”. This method is named “method #B”.

Supplement for 1 encoded block z bit.

In the case of the “LDPC encoding method using puncture”, an LDPC code (LDPC block code) having a code length (block length) of z + γ bits (γ is a natural number) is encoded to obtain z + γ bit data. Then, the γ bit is punctured (a γ bit not to be transmitted is determined) to obtain z-bit data to be transmitted. In the case of “LDPC encoding method using puncture”, “1 encoded block z bits” means “the data to be transmitted is z bits”.

In the case of “LDPC encoding method without puncturing”, an LDPC code (LDPC block code) having a code length of z bits is encoded, z-bit data is obtained, and the z-bit data is transmitted. “One encoded block z bits” means “the data to be transmitted is z bits”.

FIG. 15 is an example showing which one of “method #A” and “method #B” is used for the number of bits z and the coding rate of one encoded block. In the case of “method #A”, the coding rate is not the coding rate of the LDPC code (not the coding rate before puncturing) but the coding rate after puncturing (after deleting the bits that are not transmitted). Means.

In the example of FIG. 15, when 1 coding block z = 16200 bits, coding rates 5/15, 6/15, 7/15, and 8/15 are realized by “method #A”, and coding rate 9 / 15, 10/15, 11/15, 12/15, and 13/15 are realized by “method #B”.

When one encoded block z = 64800 bits, the encoding rate is 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12/15, 13 /. 15 is realized by “method #B”.

The feature of FIG. 15 is that “the transmitting device and the receiving device support the number of bits x of one encoded block (x is a natural number) and the number of bits y of one encoded block (y is a natural number), and x> y is satisfied. When the number of bits of one encoded block is x (x is a natural number), “method #B” is used at all coding rates, and when the number of bits of one encoded block is y, “method #A” is selected. There is a coding rate to be adopted. " Therefore, in FIG. 15, “method #A” is used at coding rates of 5/15, 6/15, 7/15, and 8/15 at z = 16200 bits (however, FIG. 15 is merely an example). Yes, it suffices if there is an encoding rate of “method #A” at z = 16200 bits).

Further, as described before, FIG. 15 supports “the number of bits x of one encoded block (x is a natural number) and the number of bits y of one encoded block (y is a natural number) at a certain coding rate. When x> y holds, “method #B” is used when the number of bits of one encoded block is x, and “method #A” is used when the number of bits of one encoded block is y. (However, at another coding rate, both of the number of bits of one encoded block x and the number of bits y of one encoded block may be “method #B”.) .

FIG. 16 is an example different from FIG. 15 showing which of “method #A” and “method #B” is used for the number of bits z and the coding rate of one encoded block. In the case of “method #A”, the coding rate is not the coding rate of the LDPC code (not the coding rate before puncturing) but the coding rate after puncturing (after deleting the bits that are not transmitted). Means.

In the example of FIG. 16, when one encoded block z is 10000 bits or more and 20000 bits or less, the coding rate 5/15, 6/15, 7/15 is realized by the “method #A”, and the coding rate 8 / 15, 9/15, 10/15, 11/15, 12/15, 13/15 are realized by “method #B”.

When one encoded block z is 50000 bits or more and 70000 bits or less, the coding rate is 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12 / 15, 13/15 is realized by “method #B”.

As described above, the feature of FIG. 16 is that, at a certain coding rate, the number of bits x of one encoded block (x is a natural number) and the number of bits y of one encoded block (y is a natural number) are supported. When x> y holds, “method #B” is used when the number of bits of one encoded block is x, and “method #A” is used when the number of bits of one encoded block is y. (However, at another coding rate, both the number of bits of one encoded block x and the number of bits y of one encoded block may be “method #B”).

FIG. 17 shows an example of the configuration of the transmission apparatus. Components that operate in the same manner as in FIG. 1 are given the same numbers, and descriptions thereof are omitted. 17 receives information 101 and control information 102 as input, and performs error correction coding processing based on FIG. 15 or FIG.

For example, the case based on FIG. 15 will be described.

The control information 102 includes information on the number of bits z of one encoded block of the error correction code (LDPC code) and information on the coding rate at the time of error correction coding (the coding rate after puncturing when performing puncturing). Is included.

However, in the case of “method #A”, the coding rate at the time of error correction coding is not the coding rate of the LDPC code (not the coding rate before puncturing), but after puncturing (deleting bits that are not transmitted) This means the coding rate. In the case of “method #B”, it means the coding rate of the LDPC code.

Therefore, for example, based on FIG. 15, the encoding unit 103 receives information 101 and control information 102 as input, and information on the number of bits z of one encoded block of an error correction code (LDPC code) included in the control information 102 Based on the coding rate information at the time of error correction coding, error correction coding (including puncture processing) is performed on the information 101, and data 104 after error correction coding is output.

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 1200 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 5/15 is indicated, the encoding unit 101 performs encoding of “method #A” corresponding to the encoding rate 5/15 (as described above, performs encoding of the LDPC code). , Perform puncturing (select a bit not to be transmitted and determine data to be transmitted).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 1200 bits, and the information of the coding rate at the time of error correction coding is the coding rate. In the case of 6/15, the encoding unit 101 performs encoding of “method #A” corresponding to the encoding rate of 6/15 (as described above, performs encoding of the LDPC code). , Perform puncturing (select a bit not to be transmitted and determine data to be transmitted).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 1200 bits, and the information of the coding rate at the time of error correction coding is the coding rate. 7/15, the encoding unit 101 performs encoding of “method #A” corresponding to the encoding rate of 7/15 (as described above, performs encoding of the LDPC code). , Perform puncturing (select a bit not to be transmitted and determine data to be transmitted).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 1200 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 8/15 is indicated, the encoding unit 101 performs encoding of “method #A” corresponding to the encoding rate 8/15 (as described above, performs encoding of the LDPC code). , Perform puncturing (select a bit not to be transmitted and determine data to be transmitted).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 1200 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 9/15 is indicated, the encoding unit 101 performs encoding of “method #B” corresponding to the encoding rate 9/15 (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 1200 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 10/15 is indicated, the encoding unit 101 performs encoding of “method #B” corresponding to the encoding rate 10/15 (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 1200 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 11/15 is indicated, the encoding unit 101 performs encoding of “method #B” corresponding to the encoding rate 11/15 (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 1200 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 12/15 is indicated, the encoding unit 101 performs encoding of “method #B” corresponding to the encoding rate of 12/15 (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 1200 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 13/15 is indicated, the encoding unit 101 performs encoding of “method #B” corresponding to the encoding rate 13/15 (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 64800 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 5/15 is indicated, the encoding unit 101 performs encoding of “method #B” corresponding to the encoding rate of 5/15 (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 64800 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 6/15 is indicated, the encoding unit 101 performs encoding of “method #B” corresponding to the encoding rate of 6/15 (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 64800 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 7/15 is indicated, the encoding unit 101 performs encoding of “method #B” corresponding to the encoding rate 7/15 (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 64800 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 8/15 is indicated, the encoding unit 101 performs encoding of “method #B” corresponding to the encoding rate of 8/15 (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 64800 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 9/15 is indicated, the encoding unit 101 performs encoding of “method #B” corresponding to the encoding rate 9/15 (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 64800 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 10/15 is indicated, the encoding unit 101 performs encoding of “method #B” corresponding to the encoding rate 10/15 (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 64800 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 11/15 is indicated, the encoding unit 101 performs encoding of “method #B” corresponding to the encoding rate 11/15 (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 64800 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 12/15 is indicated, the encoding unit 101 performs encoding of “method #B” corresponding to the encoding rate of 12/15 (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates z = 64800 bits, and the information of the coding rate at the time of error correction coding is the coding rate. When 13/15 is indicated, the encoding unit 101 performs encoding of “method #B” corresponding to the encoding rate 13/15 (as described above, puncturing is not performed).

For example, based on FIG. 16, the encoding unit 103 receives information 101 and control information 102 as input, and information on the number of bits z of an encoded block of an error correction code (LDPC code) included in the control information 102 and an error. Based on the coding rate information at the time of correction coding, error correction coding (including puncture processing) is performed on the information 101, and data 104 after error correction coding is output.

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the coding rate at the time of error correction coding If the information in FIG. 5 indicates the coding rate 5/15, the coding unit 101 performs coding of “method #A” corresponding to the coding rate 5/15 (as described above, the LDPC The code is encoded and punctured (bits not to be transmitted are selected and data to be transmitted is determined).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the coding rate at the time of error correction coding The encoding unit 101 performs encoding of “method #A” corresponding to the encoding rate 6/15 (as described above, the LDPC). The code is encoded and punctured (bits not to be transmitted are selected and data to be transmitted is determined).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the coding rate at the time of error correction coding When the information in FIG. 5 indicates the coding rate 7/15, the coding unit 101 performs coding of “method #A” corresponding to the coding rate 7/15 (as described above, the LDPC The code is encoded and punctured (bits not to be transmitted are selected and data to be transmitted is determined).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the coding rate at the time of error correction coding If the information indicates the coding rate 8/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 8/15 (as described above, puncturing). Do not do).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the coding rate at the time of error correction coding If the information indicates the coding rate 9/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 9/15 (as described above, puncturing). Do not do).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the coding rate at the time of error correction coding If the information indicates the coding rate 10/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 10/15 (as described above, puncturing). Do not do).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the coding rate at the time of error correction coding If the information indicates the coding rate 11/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 11/15 (as described above, puncturing). Do not do).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the coding rate at the time of error correction coding If the information indicates the coding rate 12/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 12/15 (as described above, puncturing). Do not do).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the coding rate at the time of error correction coding If the information indicates the coding rate 13/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 13/15 (as described above, puncturing). Do not do).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the coding rate at the time of error correction coding If the information indicates the coding rate 5/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 5/15 (as described above, puncturing). Do not do).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the coding rate at the time of error correction coding If the information indicates the coding rate 6/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 6/15 (as described above, puncturing). Do not do).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the coding rate at the time of error correction coding When the information indicates the coding rate 7/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 7/15 (as described above, puncturing). Do not do).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the coding rate at the time of error correction coding If the information indicates the coding rate 8/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 8/15 (as described above, puncturing). Do not do).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the coding rate at the time of error correction coding If the information indicates the coding rate 9/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 9/15 (as described above, puncturing). Do not do).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the coding rate at the time of error correction coding If the information indicates the coding rate 10/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 10/15 (as described above, puncturing). Do not do).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the coding rate at the time of error correction coding If the information indicates the coding rate 11/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 11/15 (as described above, puncturing). Do not do).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the coding rate at the time of error correction coding If the information indicates the coding rate 12/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 12/15 (as described above, puncturing). Do not do).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the coding rate at the time of error correction coding If the information indicates the coding rate 13/15, the coding unit 101 performs coding of “method #B” corresponding to the coding rate 13/15 (as described above, puncturing). Do not do).

The information generation unit 1701 of the number of bits of the encoded block receives the control information 102, extracts information on the number of bits z of one encoded block of the error correction code (LDPC code) included in the control information 102, and outputs control information Information 1702 on the number of bits of one encoded block for forming a symbol is output.

A coding rate information generation unit 1703 receives control information 102 as input, and stores information on a coding rate at the time of error correction coding included in the control information 102 (or a coding rate after puncturing when performing puncturing). Extraction is performed and coding rate information 1704 at the time of error correction coding for forming control information symbols is output.

Other control information generation section 1705 receives control information 102 as input, information on the number of bits of one encoded block for forming a control information symbol, and codes for error correction encoding for forming a control information symbol Control information 1706 for forming control information symbols other than the conversion rate information is output.

The control information symbol generation unit 1707 receives as input the information 1702 of the number of bits of one encoded block, the information 1704 of the coding rate at the time of error correction coding, and the control information 1706. For example, error control coding, mapping, etc. Processing is performed to output a baseband signal 1708 of control information symbols.

Radio section 112 receives control information 102, baseband signal 110, pilot signal 111, and baseband signal 1708 of a control information symbol, and based on information related to the frame configuration included in control information 102, a transmission signal based on the frame configuration 113 is generated and output (for example, when OFDM (Orthogonal Frequency Division Multiplexing) is used, processing such as inverse Fourier transform and frequency transform is performed).

FIG. 18 shows an example of a frame configuration of a modulation signal transmitted by the transmission apparatus of FIG. 17 (an example of a frame configuration when one modulation signal is transmitted). In FIG. 18, the vertical axis represents time, and the horizontal axis represents frequency. For example, in the case of a multicarrier scheme such as OFDM (OrthogonalequFrequency Division Multiplexing), there are a plurality of carriers. Shall exist. In FIG. 18, time $ 1 to time $ 8 are shown.

18, “C” indicates a control information symbol, “P” indicates a pilot symbol, and “D” indicates a data symbol. As described above, the control information symbol includes information on the number of bits of one coding block and coding rate information at the time of error correction coding, as described with reference to FIG. Suppose that

A pilot symbol is a symbol for a receiving apparatus that receives a modulated signal transmitted by a transmitting apparatus to perform channel estimation (estimation of propagation path fluctuation), frequency synchronization, time synchronization, signal detection, frequency offset estimation, and the like. The pilot symbol is a known symbol modulated by using PSK (Phase Shift Keying) modulation in the transmitter / receiver (or the receiver knows the symbol transmitted by the transmitter by synchronizing the receiver). It may be possible.)

The data symbol is, for example, a symbol for transmitting data after error correction coding generated based on FIG. 15 or FIG. 16 (note that one encoded block of data after error correction coding is The number of bits and the coding rate at the time of error correction coding are specified by the information on the number of bits of one coding block included in the control information symbol and the coding rate information at the time of error correction coding. The number of bits of one encoded block and the encoding rate at the time of error correction encoding).

Next, the operation of the receiving device that receives the modulated signal transmitted by the transmitting device in FIG. 17 will be described.

The configuration of the receiving apparatus that receives the modulated signal transmitted by the transmitting apparatus in FIG. 17 is as indicated by 150 in FIG. In the following, in particular, the operations of the control information demodulating unit 159 and the decoding unit 167 in the receiving apparatus 150 of FIG. 1 will be described in detail.

FIG. 19 is a diagram illustrating a configuration of portions related to the control information demodulating unit 159 and the decoding unit 167 in the receiving apparatus 150 of FIG.

The control information demodulating unit 159 includes a bit number information / coding rate information estimation unit 1903 of one encoded block, and a bit number information / coding rate information estimation unit 1903 of one encoded block The band signal 1902 is input, the control information symbol shown in FIG. 18 is extracted, and the information on the number of bits of one encoded block and the information on the coding rate at the time of error correction coding are further extracted from the control information symbol. As a result, the estimation signal 1904 of the information of the number of bits of one encoded block and the information of the coding rate at the time of error correction coding is output.

The puncture bit log likelihood ratio generation unit 1905 receives as input the information on the number of bits of one coding block and the estimation signal 1904 of coding rate information at the time of error correction coding, and FIG. 15 or FIG. The method used by the transmission apparatus to generate data symbol data from the information on the number of bits of one encoded block and the information on the coding rate at the time of error correction coding is shown in FIG. 16 is used to determine whether “method #A” or “method #B”, and if “method #B” is determined, bits punctured by the transmission device (bits not transmitted by the transmission device) The log likelihood ratio 106 of the bit corresponding to) is generated and output.

For example, when the transmission apparatus in FIG. 17 performs encoding based on FIG. 15 and transmits a modulated signal, the puncture bit log likelihood ratio generation unit 1905 makes the following determination.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 16200 bits, and when the coding rate information at the time of error correction coding indicates a coding rate of 5/15, the puncture bit log likelihood ratio generation unit 1905 transmits the data symbol of the data symbol. The method used to generate the data is determined as “method #A”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 16,200 bits, and when the coding rate information at the time of error correction coding indicates a coding rate of 6/15, the puncture bit log likelihood ratio generation unit 1905 transmits the data symbol The method used to generate the data is determined as “method #A”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 16200 bits, and when the information of the coding rate at the time of error correction coding indicates the coding rate 7/15, the puncture bit log likelihood ratio generation unit 1905 indicates that the transmission device is a data symbol. The method used to generate the data is determined as “method #A”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 16200 bits, and when the information of the coding rate at the time of error correction coding indicates the coding rate 8/15, the puncture bit log likelihood ratio generation unit 1905 has the data symbol of the data symbol The method used to generate the data is determined as “method #A”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 16,200 bits, and when the coding rate information at the time of error correction coding indicates a coding rate of 9/15, the puncture bit log likelihood ratio generation unit 1905 transmits the data symbol. The method used to generate the data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 16,200 bits, and when the information of the coding rate at the time of error correction coding indicates the coding rate 10/15, the puncture bit log likelihood ratio generation unit 1905 indicates that the transmission apparatus is a data symbol. The method used to generate the data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 16200 bits, and when the information of the coding rate at the time of error correction coding indicates the coding rate 11/15, the puncture bit log-likelihood ratio generation unit 1905 has a data symbol of the transmission apparatus. The method used to generate the data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 16200 bits, and when the information of the coding rate at the time of error correction coding indicates the coding rate 12/15, the puncture bit log likelihood ratio generation unit 1905 has the data symbol of the data symbol. The method used to generate the data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 16200 bits, and when the information of the coding rate at the time of error correction coding indicates the coding rate 13/15, the puncture bit log likelihood ratio generation unit 1905 indicates that the transmission apparatus The method used to generate the data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 64800 bits, and when the coding rate information at the time of error correction coding indicates a coding rate of 5/15, the puncture bit log-likelihood ratio generation unit 1905 transmits the data symbol of the data symbol. The method used to generate the data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 64800 bits, and when the coding rate information at the time of error correction coding indicates a coding rate of 6/15, the puncture bit log-likelihood ratio generation unit 1905 transmits the data symbol of the data symbol. The method used to generate the data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 64800 bits, and when the information of the coding rate at the time of error correction coding indicates the coding rate 7/15, the puncture bit log-likelihood ratio generation unit 1905 indicates that the transmission apparatus uses the data symbol. The method used to generate the data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 64800 bits, and when the coding rate information at the time of error correction coding indicates a coding rate of 8/15, the puncture bit log-likelihood ratio generation unit 1905 transmits the data symbol of the data symbol. The method used to generate the data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 64800 bits, and when the information of the coding rate at the time of error correction coding indicates the coding rate 9/15, the puncture bit log likelihood ratio generation unit 1905 has the data symbol of the data symbol. The method used to generate the data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 64800 bits, and when the information of the coding rate at the time of error correction coding indicates the coding rate 10/15, the puncture bit log likelihood ratio generation unit 1905 indicates that the transmission apparatus is a data symbol. The method used to generate the data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 64800 bits, and when the information of the coding rate at the time of error correction coding indicates the coding rate 11/15, the puncture bit log likelihood ratio generation unit 1905 indicates that the transmission apparatus uses the data symbol. The method used to generate the data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 64800 bits, and when the information of the coding rate at the time of error correction coding indicates the coding rate 12/15, the puncture bit log-likelihood ratio generation unit 1905 transmits the data symbol of the data symbol. The method used to generate the data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are the information on the number of bits z of one encoded block of the error correction code (LDPC code). = 64800 bits, and when the information of the coding rate at the time of error correction coding indicates the coding rate 13/15, the puncture bit log likelihood ratio generation unit 1905 transmits the data symbol of the data symbol. The method used to generate the data is determined as “method #B”.

For example, when the transmission apparatus in FIG. 17 performs encoding based on FIG. 16 and transmits a modulated signal, the puncture bit log likelihood ratio generation unit 1905 makes the following determination.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 10000 bits or more and 20000 bits or less ”, and when the information of the coding rate at the time of error correction coding indicates the coding rate 5/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate the data symbol data is determined as “method #A”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 10,000 bits or more and 20000 bits or less ”, and when the information of the coding rate at the time of error correction coding indicates the coding rate 6/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate the data symbol data is determined as “method #A”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 10,000 bits or more and 20000 bits or less ”, and when the information of the coding rate at the time of error correction coding indicates the coding rate 7/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate the data symbol data is determined as “method #A”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 10,000 bits or more and 20000 bits or less ", and when the information of the coding rate at the time of error correction coding indicates the coding rate 8/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 10,000 bits or more and 20000 bits or less ”, and when the information of the coding rate at the time of error correction coding indicates the coding rate 9/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 10,000 bits or more and 20000 bits or less ", and when the information of the coding rate at the time of error correction coding indicates the coding rate 10/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 10,000 bits or more and 20000 bits or less ", and when the information of the coding rate at the time of error correction coding indicates the coding rate 11/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 10,000 bits or more and 20000 bits or less ”, and when the information of the coding rate at the time of error correction coding indicates the coding rate 12/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 10,000 bits or more and 20000 bits or less ”, and when the information of the coding rate at the time of error correction coding indicates the coding rate 13/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 50000 bits or more and 70000 bits or less ", and when the information of the coding rate at the time of error correction coding indicates the coding rate 5/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 50000 bits or more and 70000 bits or less ", and when the coding rate information at the time of error correction coding indicates the coding rate 6/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 50000 bits or more and 70000 bits or less ", and when the information of the coding rate at the time of error correction coding indicates the coding rate 7/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 50000 bits or more and 70000 bits or less ", and when the information of the coding rate at the time of error correction coding indicates the coding rate 8/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 50000 bits or more and 70000 bits or less ", and when the information of the coding rate at the time of error correction coding indicates the coding rate 9/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 50000 bits or more and 70000 bits or less ”, and when the information of the coding rate at the time of error correction coding indicates the coding rate 10/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 50000 bits or more and 70000 bits or less ”, and when the information of the coding rate at the time of error correction coding indicates the coding rate 11/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 50000 bits or more and 70000 bits or less ”, and when the information of the coding rate at the time of error correction coding indicates the coding rate 12/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

The information on the number of bits of one encoded block and the estimation signal 1904 of the information on the coding rate at the time of error correction encoding are information on the number of bits z of one encoded block of an error correction code (LDPC code). z is 50000 bits or more and 70000 bits or less ", and when the information of the coding rate at the time of error correction coding indicates the coding rate 13/15, the puncture bit log likelihood ratio generation unit 1905 The method used by the transmitting apparatus to generate data symbol data is determined as “method #B”.

(Embodiment B)
A modification of the embodiment A will be described.

An example of which one of “method #A” and “method #B” is used for one encoded block number z and a coding rate is as described in FIGS. 15 and 16 of the embodiment A. The description is omitted.

The configuration of the transmission apparatus is as described with reference to FIG. 17 of Embodiment A, and a part of the description is omitted.

FIG. 20 shows an example of the frame configuration of the modulation signal transmitted by the transmission apparatus of FIG. In FIG. 20, the vertical axis represents frequency and the horizontal axis represents time. Since a transmission method using multicarriers such as the OFDM method is used, it is assumed that there are a plurality of carriers in the vertical axis frequency.

20, 2001 indicates a first preamble, 2002 indicates a second preamble, 2003 indicates a data

symbol group #

1, 2004 indicates a data

symbol group #

2, and 2005 indicates a data symbol group # 3.

Explanation of data symbol group. In the case of a broadcasting system, a data symbol group may be assigned for each video / audio. For example, the symbol for transmitting the first video / audio stream is data symbol group # 1 (2003), and the symbol for transmitting the second video / audio stream is data symbol group # 2 (2004). The symbol for transmitting the third video / audio stream is the data symbol group # 3 (note that PLP (Physical Layer Pipe) may be used as the data symbol group. At this time, the data symbol group # 1 is used as the data symbol group # 1. PLP # 1, data symbol group # 2 may be named PLP # 2, and data symbol group # 3 may be named PLP # 3).

The first preamble 2001 and the second preamble 2002 include symbols for performing frequency synchronization and time synchronization (for example, PSK (Phase Shift Keying) for which the signal point arrangement is known in the in-phase I-orthogonal plane for the transceiver). Symbols), transmission symbols for each data symbol group (SISO (Single-Input to Single-Output) system, MISO (Multiple-Input to Single-Output) system, information for identifying the MIMO system)), symbols to transmit, and data Symbols for transmitting information relating to error correction codes of symbol groups (for example, code length (number of bits of one encoded block), coding rate), information relating to modulation scheme of each data symbol group (MISO scheme or MIMO) In the case of a scheme, since there are multiple streams, multiple modulation schemes are specified) A symbol for transmitting the transmission method information of the first and second preambles, a symbol for transmitting information about the modulation schemes of the first and second preambles, a symbol for transmitting information about the insertion method of the pilot symbols, It is assumed that a symbol or the like for transmitting information on a PAPR (Peak-to-Average Power Ratio) suppression method is included.

In the present embodiment, as in Embodiment A, in particular, information on the number of bits of one encoded block of each data symbol group and information on coding rate at the time of error correction coding of each data symbol group are provided. It is assumed that it is included in the first preamble (2001) and / or the second preamble (2002). Therefore, in the case of the frame configuration of FIG. 20, information on the number of bits of one encoded block of data symbol group # 1, information on coding rate at the time of error correction code of data symbol group # 1, and data symbol group # Information on the number of bits in one encoded block of 2 and information on the coding rate in error correction code of data symbol group # 2, and information on the number of bits in one encoded block of data symbol group # 3 and data symbols It is assumed that coding rate information for the error correction code of group # 3 is included in the first preamble (2001) and / or the second preamble (2002).

At this time, the following is performed for each data symbol group. In the case of the frame configuration in FIG. 20, X is set to 1, 2, and 3, and the following is performed.

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 1200 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates a coding rate of 5/15, in order to generate data for forming the data symbol group #X, the coding unit 101 performs coding rate 5/15. (As described above, the LDPC code is encoded and punctured (a bit to be transmitted is selected and data to be transmitted is determined)).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 1200 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 6/15, the coding unit 101 generates the coding rate 6/15 in order to generate data for forming the data symbol group #X. (As described above, the LDPC code is encoded and punctured (a bit to be transmitted is selected and data to be transmitted is determined)).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 1200 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 7/15, the coding unit 101 generates the coding rate 7/15 in order to generate data for forming the data symbol group #X. (As described above, the LDPC code is encoded and punctured (a bit to be transmitted is selected and data to be transmitted is determined)).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 1200 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 8/15, the coding unit 101 generates the coding rate 8/15 in order to generate data for forming the data symbol group #X. (As described above, the LDPC code is encoded and punctured (a bit to be transmitted is selected and data to be transmitted is determined)).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 1200 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 9/15, the coding unit 101 generates the coding rate 9/15 in order to generate data for forming the data symbol group #X. (Method #B) corresponding to is encoded (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 1200 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 10/15, the coding unit 101 generates the coding rate 10/15 in order to generate data for forming the data symbol group #X. (Method #B) corresponding to is encoded (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 1200 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 11/15, the coding unit 101 generates the coding rate 11/15 in order to generate data for forming the data symbol group #X. (Method #B) corresponding to is encoded (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 1200 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 12/15, the coding unit 101 generates the coding rate 12/15 in order to generate data for forming the data symbol group #X. (Method #B) corresponding to is encoded (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 1200 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 13/15, the coding unit 101 generates the coding rate 13/15 in order to generate data for forming the data symbol group #X. (Method #B) corresponding to is encoded (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 64800 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates a coding rate of 5/15, in order to generate data for forming the data symbol group #X, the coding unit 101 performs coding rate 5/15. (Method #B) corresponding to is encoded (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 64800 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 6/15, the coding unit 101 generates the coding rate 6/15 in order to generate data for forming the data symbol group #X. (Method #B) corresponding to is encoded (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 64800 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 7/15, the coding unit 101 generates the coding rate 7/15 in order to generate data for forming the data symbol group #X. (Method #B) corresponding to is encoded (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 64800 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 8/15, the coding unit 101 generates the coding rate 8/15 in order to generate data for forming the data symbol group #X. (Method #B) corresponding to is encoded (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 64800 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 9/15, the coding unit 101 generates the coding rate 9/15 in order to generate data for forming the data symbol group #X. (Method #B) corresponding to is encoded (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 64800 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 10/15, the coding unit 101 generates the coding rate 10/15 in order to generate data for forming the data symbol group #X. (Method #B) corresponding to is encoded (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 64800 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 11/15, the coding unit 101 generates the coding rate 11/15 in order to generate data for forming the data symbol group #X. (Method #B) corresponding to is encoded (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 64800 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 12/15, the coding unit 101 generates the coding rate 12/15 in order to generate data for forming the data symbol group #X. (Method #B) corresponding to is encoded (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates z = 64800 bits, and the error correction encoding of the data symbol group #X When the coding rate information at this time indicates the coding rate 13/15, the coding unit 101 generates the coding rate 13/15 in order to generate data for forming the data symbol group #X. (Method #B) corresponding to is encoded (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the data symbol group # In order to generate data for forming the data symbol group #X when the coding rate information at the time of error correction coding of X indicates the coding rate 5/15, the coding unit 101 Encode “Method #A” corresponding to an encoding rate of 5/15 (encode LDPC code and perform puncture as described above (select non-transmitted bits and transmit data) Decide)).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the data symbol group # When the coding rate information at the time of error correction coding of X indicates coding rate 6/15, in order to generate data for forming the data symbol group #X, the coding unit 101 Encode “Method #A” corresponding to an encoding rate of 6/15 (as described above, encode LDPC code and perform puncture (select non-transmitted bits and transmit data) Decide)).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the data symbol group # In order to generate data for forming the data symbol group #X when the coding rate information at the time of error correction coding of X indicates the coding rate 7/15, the coding unit 101 Encode “Method #A” corresponding to an encoding rate of 7/15 (as described above, encode LDPC code and perform puncture (select non-transmitted bits and transmit data) Decide)).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the data symbol group # When the coding rate information at the time of error correction coding of X indicates the coding rate 8/15, in order to generate data for forming the data symbol group #X, the coding unit 101 Encoding of “method #B” corresponding to an encoding rate of 8/15 is performed (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the data symbol group # When the coding rate information at the time of error correction coding of X indicates the coding rate 9/15, in order to generate data for forming the data symbol group #X, the coding unit 101 Encoding of “method #B” corresponding to an encoding rate of 9/15 is performed (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the data symbol group # When the coding rate information at the time of error correction coding of X indicates the coding rate 10/15, in order to generate data for forming the data symbol group #X, the coding unit 101 Encoding of “method #B” corresponding to an encoding rate of 10/15 is performed (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the data symbol group # When the coding rate information at the time of error correction coding of X indicates the coding rate 11/15, in order to generate data for forming the data symbol group #X, the coding unit 101 Encoding of “method #B” corresponding to the encoding rate 11/15 is performed (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the data symbol group # When the coding rate information at the time of error correction coding of X indicates coding rate 12/15, in order to generate data for forming the data symbol group #X, the coding unit 101 Encoding of “method #B” corresponding to the encoding rate 12/15 is performed (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 10000 bits or more and 20000 bits or less”, and the data symbol group # When the coding rate information at the time of error correction coding of X indicates coding rate 13/15, in order to generate data for forming data symbol group #X, coding section 101 Encoding of “method #B” corresponding to the coding rate 13/15 is performed (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the data symbol group # In order to generate data for forming the data symbol group #X when the coding rate information at the time of error correction coding of X indicates the coding rate 5/15, the coding unit 101 Encoding of “method #B” corresponding to an encoding rate of 5/15 is performed (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the data symbol group # When the coding rate information at the time of error correction coding of X indicates coding rate 6/15, in order to generate data for forming the data symbol group #X, the coding unit 101 Encoding of “method #B” corresponding to an encoding rate of 6/15 is performed (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the data symbol group # In order to generate data for forming the data symbol group #X when the coding rate information at the time of error correction coding of X indicates the coding rate 7/15, the coding unit 101 Encoding of “method #B” corresponding to an encoding rate of 7/15 is performed (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the data symbol group # When the coding rate information at the time of error correction coding of X indicates the coding rate 8/15, in order to generate data for forming the data symbol group #X, the coding unit 101 Encoding of “method #B” corresponding to an encoding rate of 8/15 is performed (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the data symbol group # When the coding rate information at the time of error correction coding of X indicates the coding rate 9/15, in order to generate data for forming the data symbol group #X, the coding unit 101 Encoding of “method #B” corresponding to an encoding rate of 9/15 is performed (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the data symbol group # When the coding rate information at the time of error correction coding of X indicates the coding rate 10/15, in order to generate data for forming the data symbol group #X, the coding unit 101 Encoding of “method #B” corresponding to an encoding rate of 10/15 is performed (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the data symbol group # When the coding rate information at the time of error correction coding of X indicates the coding rate 11/15, in order to generate data for forming the data symbol group #X, the coding unit 101 Encoding of “method #B” corresponding to the encoding rate 11/15 is performed (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the data symbol group # When the coding rate information at the time of error correction coding of X indicates coding rate 12/15, in order to generate data for forming the data symbol group #X, the coding unit 101 Encoding of “method #B” corresponding to the encoding rate 12/15 is performed (as described above, puncturing is not performed).

The information of the number of bits z of one encoded block of the error correction code (LDPC code) of the data symbol group #X included in the control information 102 indicates that “z is 50000 bits or more and 70000 bits or less”, and the data symbol group # When the coding rate information at the time of error correction coding of X indicates coding rate 13/15, in order to generate data for forming data symbol group #X, coding section 101 Encoding of “method #B” corresponding to the coding rate 13/15 is performed (as described above, puncturing is not performed).

The control information demodulating unit 159 includes a bit number information / coding rate information estimation unit 1903 of one encoded block, and a bit number information / coding rate information estimation unit 1903 of one encoded block The band signal 1902 is input, the first preamble and / or the second preamble shown in FIG. 20 is extracted, and further, information on the number of bits of one encoded block from the first preamble and / or the second preamble, and Then, information on the coding rate at the time of error correction coding is obtained, and information on the number of bits of one coding block and an estimation signal 1904 of information on the coding rate at the time of error correction coding are output.

In the case of the present embodiment, the transmission device in FIG. 17 transmits a modulation signal having a frame configuration based on FIG. 20, and the reception device 150 in FIG. 1 receives this modulation signal. At this time, receiving apparatus 150 in FIG. 1 performs a demodulation / decoding operation to obtain data of a required data symbol group among a plurality of data symbol groups. Therefore, the control information demodulating unit 159 obtains “information on the number of bits of one encoded block and information on the coding rate at the time of error correction encoding” of the required data symbol group. An estimated signal 1904 of information on the number of bits and coding rate information at the time of error correction coding is output.

The puncture bit log likelihood ratio generation unit 1905 receives as input the information on the number of bits of one coding block and the estimation signal 1904 of coding rate information at the time of error correction coding, and FIG. 15 or FIG. The method used by the transmission apparatus to generate data symbol data from the information on the number of bits of one encoded block and the information on the coding rate at the time of error correction coding is shown in FIG. 16 is used to determine whether “method #A” or “method #B”, and if “method #B” is determined, bits punctured by the transmission device (bits not transmitted by the transmission device) The log likelihood ratio 106 of the bit corresponding to) is generated and output. Note that, when the “puncture bit log likelihood ratio generation unit 1905 determines“ method #B ”, the log likelihood ratio 106 of the bit corresponding to the bit punctured by the transmission apparatus (bit not transmitted by the transmission apparatus). Is generated and output. However, the log likelihood ratio 106 of bits corresponding to the punctured bits (bits not transmitted by the transmission device) for the necessary data symbol group is generated and output.

For example, when the transmission apparatus in FIG. 17 performs encoding based on FIG. 15 and transmits a modulation signal having a frame configuration based on FIG. 20, the puncture bit log likelihood ratio generation unit 1905 performs the following for each data symbol group: The following determination is made (X is 1, 2, and 3).

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 1200 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 5/15, the puncture bit log likelihood The ratio generation unit 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #A”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 1200 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 6/15, the puncture bit log likelihood The ratio generation unit 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #A”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 1200 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 7/15, the puncture bit log likelihood The ratio generation unit 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #A”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 1200 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 8/15, the puncture bit log likelihood The ratio generation unit 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #A”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 1200 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 9/15, the puncture bit log likelihood The ratio generator 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 1200 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 10/15, the puncture bit log likelihood The ratio generator 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 1200 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 11/15, the puncture bit log likelihood The ratio generator 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 1200 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 12/15, the puncture bit log likelihood The ratio generator 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 1200 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 13/15, the puncture bit log likelihood The ratio generator 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 64800 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 5/15, the puncture bit log likelihood The ratio generator 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 64800 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 6/15, the puncture bit log likelihood The ratio generator 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 64800 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 7/15, the puncture bit log likelihood The ratio generator 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 64800 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 8/15, the puncture bit log likelihood The ratio generator 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 64800 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 9/15, the puncture bit log likelihood The ratio generator 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 64800 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 10/15, the puncture bit log likelihood The ratio generator 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 64800 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 11/15, the puncture bit log likelihood The ratio generator 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 64800 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 12/15, the puncture bit log likelihood The ratio generator 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates z = 64800 bits and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 13/15, the puncture bit log likelihood The ratio generator 1905 determines that the method used by the transmission apparatus to generate data of the data symbol group #X is “method #B”.

For example, when the transmission apparatus of FIG. 17 performs encoding based on FIG. 16 and transmits a modulation signal having a frame configuration based on FIG. 20, the puncture bit log likelihood ratio generation unit 1905 performs for each data symbol group, The following determination is made (X is 1, 2, and 3).

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 10000 bits or more and 20000 bits or less”, and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 5/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #A”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 10,000 bits or more and 20000 bits or less” and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 6/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #A”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 10,000 bits or more and 20000 bits or less”, and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 7/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #A”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 10,000 bits or more and 20000 bits or less”, and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 8/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 10,000 bits or more and 20000 bits or less”, and the coding rate information at the time of error correction coding of the data symbol group #X indicates the coding rate 9/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 10,000 bits or more and 20000 bits or less”, and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 10/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 10000 bits or more and 20000 bits or less”, and the coding rate information at the time of error correction coding of the data symbol group #X indicates the coding rate 11/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 10000 bits or more and 20000 bits or less” and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 12/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 10,000 bits or more and 20000 bits or less”, and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 13/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 50000 bits or more and 70000 bits or less” and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 5/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 50000 bits or more and 70000 bits or less” and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 6/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 50000 bits or more and 70000 bits or less” and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 7/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 50000 bits or more and 70000 bits or less” and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 8/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 50000 bits or more and 70000 bits or less” and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 9/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 50000 bits or more and 70000 bits or less” and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 10/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 50000 bits or more and 70000 bits or less”, and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 11/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 50000 bits or more and 70000 bits or less” and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 12/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

The information of the number of bits of one encoded block and the estimated signal 1904 of the coding rate information at the time of error correction encoding are bits of one encoded block of the error correction code (LDPC code) of the data symbol group #X. When the information of the number z indicates “z is 50000 bits or more and 70000 bits or less” and the information of the coding rate at the time of error correction coding of the data symbol group #X indicates the coding rate 13/15 Puncture bit log likelihood ratio generation section 1905 determines that the method used by the transmission apparatus to generate data of data symbol group #X is “method #B”.

In the embodiment A and the embodiment B, as an example showing which of “method #A” and “method #B” is used for the number of bits z and the coding rate of one encoded block, FIG. , FIG. 16 has been described. However, the assignment of “method #A” and “method #B” to the number of bits z and the coding rate of one encoded block is not limited to FIGS. 15 and 16 described in the form A of FIG. 15 are satisfied. For example, with respect to FIG. 15, z = 16800 bits, coding rate 8/15 is “method #B”, z = 16800 bits, The coding rate 9/15 may be “method #A”.

Further, in Embodiment B, FIG. 20 has been described as the frame configuration of the modulation signal transmitted by the transmission apparatus. However, the frame configuration is not limited to this, for example, one or more data symbol groups, or A frame configuration in which two or more data symbol groups exist may be used.

Although the broadcast (or communication) system according to the present disclosure has been described according to the above embodiment, the present disclosure is not limited to this.

Of course, a plurality of embodiments described in this specification and other contents may be combined.

In addition, each embodiment and other contents are merely examples. For example, “modulation method, error correction coding method (error correction code to be used, code length, coding rate, etc.), control information, etc.” Even if it is exemplified, even when another “modulation method, error correction coding method (error correction code to be used, code length, coding rate, etc.), control information, etc.” is applied, the same configuration can be used. Is possible.

Regarding the modulation method, the embodiment described in this specification and other contents can be implemented even if a modulation method other than the modulation method described in this specification is used. For example, APSK (Amplitude Phase Shift Keying) (for example, 16APSK, 64APSK, 128APSK, 256APSK, 1024APSK, 4096APSK), PAM (Pulse Amplitude Modulation) (for example, 4PAM, 8PAM, 16PAM, 64PAM, 128PAM, PAM, PAM, PAM, PAM Etc.), PSK (Phase Shift Keying) (for example, BPSK, QPSK, 8PSK, 16PSK, 64PSK, 128PSK, 256PSK, 1024PSK, 4096PSK, etc.), QAM (Quadrature Amplitude Modulation) (for example, 4QAM, , 256QAM, 1024QAM, 4096QAM, etc.) may be applied, and in each modulation method, uniform mapping or non-uniform mapping may be used (any mapping may be applied).

Further, the signal point arrangement method of 16, 64, etc. on the IQ plane (modulation method having 16, 64 signal points, etc.) is the same as the signal point arrangement method of the modulation method shown in this specification. It is not limited. Therefore, the function of outputting the in-phase component and the quadrature component based on a plurality of bits is a function in the mapping unit.

The disclosure described in this specification can be applied to a multicarrier transmission method such as the OFDM method, and can also be applied to a single carrier transmission method. (For example, in the case of a multicarrier system, symbols are also arranged on the frequency axis, but in the case of a single carrier, symbols are arranged only in the time direction.) Also, spread codes are used for baseband signals. Thus, a spread spectrum communication system can be applied.

In the present specification, a configuration in which the receiving device of the terminal and the antenna are separate may be used. For example, the receiving apparatus has an interface for inputting a signal received by an antenna or a signal obtained by performing frequency conversion on a signal received by an antenna through a cable, and the receiving apparatus performs subsequent processing. . The data / information obtained by the receiving device is then converted into video or sound and displayed on a display (monitor) or sound is output from a speaker. Further, the data / information obtained by the receiving device is subjected to signal processing related to video and sound (signal processing may not be performed), and the RCA terminal (video terminal, sound terminal), USB ( Universal (Serial Bus), USB 2, USB 3, HDMI (registered trademark) (High-Definition Multimedia Interface), HDMI (registered trademark) 2, digital terminal, etc. The data / information obtained by the receiving device is a wireless communication method (Wi-Fi (registered trademark) (IEEE 802.11a, IEEE 802.11b, IEEE 802.11g, IEEE 802.11n, IEEE 802.11ac, IEEE 802.11ad, etc.), WiGiG, Bluetooth (registered trademark, etc.)) or a wired communication method (optical communication, power line communication, etc.) may be modulated and transmitted to other devices. At this time, the terminal is equipped with a transmitting device for transmitting information (at this time, the terminal may transmit data including data / information obtained by the receiving device, or the receiving device). From the obtained data / information may be generated and transmitted).

In this specification, it is conceivable that the transmission device is equipped with a communication / broadcasting device such as a broadcasting station, a base station, an access point, a terminal, a mobile phone (mobile phone), It is conceivable that the receiving device is equipped with a communication device such as a television, a radio, a terminal, a personal computer, a mobile phone, an access point, and a base station. In addition, the transmission device and the reception device in the present disclosure are devices having a communication function, and the devices provide some interface to a device for executing an application such as a television, a radio, a personal computer, or a mobile phone. It is also conceivable that the connection is possible.

In the present embodiment, symbols other than data symbols, for example, pilot symbols (preamble, unique word, postamble, reference symbol, etc.), control information symbols, etc., are arranged in any manner. Good. Here, the pilot symbol and the control information symbol are named, but any naming method may be used, and the function itself is important.

Therefore, for example, in this specification, the name is referred to as a control information symbol, but the name is not limited to this, and another name such as a control channel may be used. In this symbol, control information such as information on a transmission method (eg, transmission method, modulation method, error correction code coding rate, error correction code length, frame configuration method, Fourier transform method (size), etc.) Is a symbol to transmit.

The pilot symbol is, for example, a known symbol modulated using PSK modulation in a transmitter / receiver (or the receiver can know the symbol transmitted by the transmitter by synchronizing the receiver). The receiver may perform frequency synchronization, time synchronization, channel estimation (estimation of CSI (Channel State Information)), signal detection, and the like using this symbol. It will be.

In addition, the control information symbol is information (for example, a modulation method, an error correction coding method used for communication, a communication information symbol) that needs to be transmitted to a communication partner in order to realize communication other than data (such as an application). This is a symbol for transmitting an error correction coding method coding rate, setting information in an upper layer, and the like.

It should be noted that the present disclosure is not limited to each embodiment, and can be implemented with various modifications. For example, in each embodiment, the case of performing as a communication device has been described. However, the present invention is not limited to this, and this communication method can also be performed as software.

In the transmitting station, the transmitting antenna of the base station, and the receiving antenna of the terminal, one antenna described in the drawings may be composed of a plurality of antennas.

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

In addition, a program for executing the 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 is operated according to the program. You may do it.

Each configuration such as the above-described embodiments may be typically realized as an LSI (Large Scale Integration) that is an integrated circuit. These may be individually made into one chip, or may be made into one chip so as to include all or part of the configurations of the respective embodiments. The name used here is LSI, but it may also be called IC (Integrated Circuit), system LSI, super LSI, or ultra LSI depending on the degree of integration. Further, the method of circuit integration is not limited to LSI's, and implementation using dedicated circuitry or general purpose processors is also possible. An FPGA (Field Programmable Gate Array) that can be programmed after manufacturing the LSI or a reconfigurable processor that can reconfigure the connection and setting of circuit cells inside the LSI may be used.

Furthermore, if integrated circuit technology that replaces LSI emerges as a result of advances in semiconductor technology or other derived technologies, it is naturally also possible to integrate functional blocks using this technology. There is a possibility of adaptation of biotechnology.

The present disclosure can be widely applied to wireless systems that transmit different modulation signals from a plurality of antennas. The present invention is also applicable to a case where MIMO transmission is performed in a wired communication system having a plurality of transmission points (for example, PLC (Power Line Communication) system, optical communication system, DSL (Digital Subscriber Line) system). be able to.

Since the transmission method, the reception method, the transmission device, and the reception device according to the present disclosure have high error correction capability, high data reception quality can be ensured.

100 transmitter 150 receiver

Claims

A transmission method using a plurality of encoding methods,
An encoding step of selecting one encoding method from the plurality of encoding methods in units of data symbols, and encoding an information sequence using the selected encoding method to obtain an encoded sequence;
Modulating the encoded sequence to obtain data symbols;
Transmitting a transmission frame configured to include a plurality of data symbol groups composed of a plurality of the data symbols, and
The plurality of encoding schemes include at least a first encoding scheme and a second encoding scheme,
The first coding scheme is a coding scheme of a first coding rate using a first parity check matrix and using the generated first codeword as a first coding sequence.
The second encoding method uses a second parity check matrix different from the first parity check matrix, and performs a puncture process on the generated second codeword, whereby the second encoding is performed. A second encoding rate encoding method after the puncturing process, which is different from the first encoding rate to generate a sequence;
The transmission method, wherein the number of bits of the first encoded sequence is equal to the number of bits of the second encoded sequence.
A receiving method using a plurality of decoding methods,
A demodulation step for demodulating the received signal;
A decoding step for error correction decoding a plurality of received values generated by demodulation, and
The received signal constitutes a frame including a plurality of data symbol groups composed of a plurality of data symbols,
The data symbol is encoded by switching the encoding method in units of the data symbol group,
In the decoding step,
When the plurality of received values are encoded by the first encoding method, the first decoding method corresponding to the first encoding method is applied to the plurality of received values. And
When the plurality of received values are encoded by the second encoding method, a depuncture process is applied to the plurality of received values, and the plurality of values after the depuncture process are Applying a second decoding method corresponding to the second encoding scheme;
The first coding scheme is a coding scheme of a first coding rate using a first parity check matrix and using the generated first codeword as a first coding sequence.
The second encoding method uses a second parity check matrix different from the first parity check matrix, and performs a puncture process on the generated second codeword, whereby the second encoding is performed. A second encoding rate encoding method after the puncturing process, which is different from the first encoding rate to generate a sequence;
A receiving method in which the number of bits of the first encoded sequence is equal to the number of bits of the second encoded sequence.
A transmission device using a plurality of encoding methods,
An encoding unit that selects one encoding method from the plurality of encoding methods on a data symbol group basis, encodes an information sequence using the selected encoding method, and obtains an encoded sequence;
A modulator for modulating the encoded sequence to obtain data symbols;
A transmission unit configured to transmit a transmission frame including a plurality of data symbol groups each including a plurality of data symbols, and
The plurality of encoding schemes include at least a first encoding scheme and a second encoding scheme,
The first coding scheme is a coding scheme of a first coding rate using a first parity check matrix and using the generated first codeword as a first coding sequence.
The second encoding method uses a second parity check matrix different from the first parity check matrix, and performs a puncture process on the generated second codeword, whereby the second encoding is performed. A second encoding rate encoding method after the puncturing process, which is different from the first encoding rate to generate a sequence;
The transmitting apparatus, wherein the number of bits of the first encoded sequence is equal to the number of bits of the second encoded sequence.
A receiving apparatus using a plurality of decoding methods,
A demodulator that demodulates the received signal;
A decoding unit that performs error correction decoding on a plurality of received values generated by the demodulation unit,
The received signal constitutes a frame including a plurality of data symbol groups composed of a plurality of data symbols,
The data symbol is encoded by switching the encoding method in units of the data symbol group,
The decoding unit
When the plurality of received values are encoded by the first encoding method, the first decoding method corresponding to the first encoding method is applied to the plurality of received values. And
When the plurality of received values are encoded by the second encoding method, a depuncture process is applied to the plurality of received values, and the plurality of values after the depuncture process are Applying a second decoding method corresponding to the second encoding scheme;
The first coding scheme is a coding scheme of a first coding rate using a first parity check matrix and using the generated first codeword as a first coding sequence.
The second encoding method uses a second parity check matrix different from the first parity check matrix, and performs a puncture process on the generated second codeword, whereby the second encoding is performed. A second encoding rate encoding method after the puncturing process, which is different from the first encoding rate to generate a sequence;
A receiving apparatus in which the number of bits of the first encoded sequence is equal to the number of bits of the second encoded sequence.