JP7497771B2 - Transmitting device, transmitting method, receiving device, and receiving method - Google Patents

Description

This technology relates to a transmitting device, a transmitting method, a receiving device, and a receiving method, and in particular to a transmitting device, a transmitting method, a receiving device, and a receiving method that can ensure good communication quality, for example, in data transmission using LDPC codes.

LDPC (Low Density Parity Check) codes have high error correction capabilities, and in recent years have been widely adopted in digital broadcasting and other transmission methods, such as DVB (Digital Video Broadcasting)-S.2 in Europe, DVB-T.2, DVB-C.2, and ATSC (Advanced Television Systems Committee) 3.0 in the United States (see, for example, Non-Patent Document 1).

Recent research has shown that LDPC codes, like turbo codes, can achieve performance approaching the Shannon limit as the code length is increased. In addition, LDPC codes have the property that the minimum distance is proportional to the code length, which gives them good block error probability characteristics. Another advantage is that the so-called error floor phenomenon observed in the decoding characteristics of turbo codes and the like hardly occurs.

ATSC Standard:Physical Layer Protocol(A/322), 7 September 2016

In data transmission using LDPC codes, for example, the LDPC codes are converted (symbolized) into symbols for orthogonal modulation (digital modulation) such as QPSK (Quadrature Phase Shift Keying), and the symbols are mapped to signal points of the orthogonal modulation and transmitted.

Data transmission using LDPC codes like those described above is becoming more widespread around the world, and there is a demand to ensure good communication (transmission) quality.

This technology was developed in light of these circumstances, and makes it possible to ensure good communication quality in data transmission using LDPC codes.

The first transmission method/apparatus of the present technology includes an encoding step/unit that performs LDPC encoding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 2/16, a group-wise interleaving step/unit that performs group-wise interleaving of the LDPC code in units of 360-bit bit groups, and a mapping step/unit that maps the LDPC code to one of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits, and in the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and a sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
46 11 23 33 10 0 17 47 20 5 38 29 28 16 41 27 2 31 43 37 34 12 35 24 21 44 40 36 32 39 4 19 26 6 30 9 42 1 22 8 3 45 14 15 13 7 25 18
and interleaving in the order of the above, the parity check matrix includes an A matrix at the top left of the parity check matrix, which has M1 rows and K columns, represented by a predetermined value M1 and an information length K=N×r of the LDPC code, a B matrix of a staircase structure adjacent to the right of the A matrix, which has M1 rows and M1 columns, a Z matrix which is a zero matrix adjacent to the right of the B matrix, which has M1 rows and N-K-M1 columns, a C matrix adjacent below the A matrix and the B matrix, which has N-K-M1 rows and K+M1 columns, and a D matrix which is an identity matrix adjacent to the right of the C matrix, which has N-K-M1 rows and N-K-M1 columns, the predetermined value M1 is 1800, the A matrix and the C matrix are represented by a parity check matrix initial value table, and the parity check matrix initial value table is a table that represents the positions of elements of 1 in the A matrix and the C matrix for every 360 columns,
485 1444 1737 3762 7283 10663
181 1563 1623 3902 12647
1077 1216 1709 11264 13865
303 1225 1369 13470 14991
1067 1226 1795 2169 2507 2677 2727 2773 3609 3926 3996 4192 5004 5921 6134 6385 7419 7595 7821 8996 9413 10318 10557 10886 11307 11599 12641 13430
101 1264 1427 1860 2032 2063 3143 3156 4227 4554 4732 5165 5447 5902 6145 6721 7170 8660 8833 9081 9643 9800 10233 11723 12547 13124 14196 14723
3403 3678 5842 7967 8991 9220 9663 10299 10343 10550
1951 2354 3899 4774 7602 9120 9666 11048 14327 15089
2588 3047 4252 4831 5220 5487 5626 6380 9410 10618
2261 2295 5693 6711 6789 8342 11569 11943 12826 14312
3441 5287 7665 7864 8134 8446 10920 11625 12710 13309
The present invention relates to a transmission method/apparatus.

In the first transmission method/apparatus of the present technology, LDPC coding is performed based on a check matrix of an LDPC code with a code length N of 17280 bits and a coding rate r of 2/16, and group-wise interleaving is performed to interleave the LDPC code in units of 360-bit bit groups. Then, the LDPC code is mapped in units of 4 bits to one of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM. In the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
46 11 23 33 10 0 17 47 20 5 38 29 28 16 41 27 2 31 43 37 34 12 35 24 21 44 40 36 32 39 4 19 26 6 30 9 42 1 22 8 3 45 14 15 13 7 25 18
The parity check matrix includes an A matrix at the top left of the parity check matrix, which has M1 rows and K columns and is represented by a predetermined value M1 and an information length K=N×r of the LDPC code, a B matrix of a staircase structure adjacent to the right of the A matrix, which has M1 rows and M1 columns, a Z matrix which is a zero matrix adjacent to the right of the B matrix, which has M1 rows and N-K-M1 columns, a C matrix adjacent below the A matrix and the B matrix, which has N-K-M1 rows and K+M1 columns, and a D matrix which is an identity matrix adjacent to the right of the C matrix, which has N-K-M1 rows and N-K-M1 columns, the predetermined value M1 is 1800, the A matrix and the C matrix are represented by a parity check matrix initial value table, and the parity check matrix initial value table is a table which represents the positions of elements of 1 in the A matrix and the C matrix for every 360 columns,
485 1444 1737 3762 7283 10663
181 1563 1623 3902 12647
1077 1216 1709 11264 13865
303 1225 1369 13470 14991
1067 1226 1795 2169 2507 2677 2727 2773 3609 3926 3996 4192 5004 5921 6134 6385 7419 7595 7821 8996 9413 10318 10557 10886 11307 11599 12641 13430
101 1264 1427 1860 2032 2063 3143 3156 4227 4554 4732 5165 5447 5902 6145 6721 7170 8660 8833 9081 9643 9800 10233 11723 12547 13124 14196 14723
3403 3678 5842 7967 8991 9220 9663 10299 10343 10550
1951 2354 3899 4774 7602 9120 9666 11048 14327 15089
2588 3047 4252 4831 5220 5487 5626 6380 9410 10618
2261 2295 5693 6711 6789 8342 11569 11943 12826 14312
3441 5287 7665 7864 8134 8446 10920 11625 12710 13309
It has become.

The first receiving device/method of the present technology includes a coding step of performing LDPC coding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 2/16, a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of 360-bit bit groups, and a mapping step of mapping the LDPC code to any of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits, wherein in the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and a sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
46 11 23 33 10 0 17 47 20 5 38 29 28 16 41 27 2 31 43 37 34 12 35 24 21 44 40 36 32 39 4 19 26 6 30 9 42 1 22 8 3 45 14 15 13 7 25 18
and interleaving in the order of the above, the parity check matrix includes an A matrix at the top left of the parity check matrix, which has M1 rows and K columns, represented by a predetermined value M1 and an information length K=N×r of the LDPC code, a B matrix of a staircase structure adjacent to the right of the A matrix, which has M1 rows and M1 columns, a Z matrix which is a zero matrix adjacent to the right of the B matrix, which has M1 rows and N-K-M1 columns, a C matrix adjacent below the A matrix and the B matrix, which has N-K-M1 rows and K+M1 columns, and a D matrix which is an identity matrix adjacent to the right of the C matrix, which has N-K-M1 rows and N-K-M1 columns, the predetermined value M1 is 1800, the A matrix and the C matrix are represented by a parity check matrix initial value table, and the parity check matrix initial value table is a table that represents the positions of elements of 1 in the A matrix and the C matrix for every 360 columns,
485 1444 1737 3762 7283 10663
181 1563 1623 3902 12647
1077 1216 1709 11264 13865
303 1225 1369 13470 14991
1067 1226 1795 2169 2507 2677 2727 2773 3609 3926 3996 4192 5004 5921 6134 6385 7419 7595 7821 8996 9413 10318 10557 10886 11307 11599 12641 13430
101 1264 1427 1860 2032 2063 3143 3156 4227 4554 4732 5165 5447 5902 6145 6721 7170 8660 8833 9081 9643 9800 10233 11723 12547 13124 14196 14723
3403 3678 5842 7967 8991 9220 9663 10299 10343 10550
1951 2354 3899 4774 7602 9120 9666 11048 14327 15089
2588 3047 4252 4831 5220 5487 5626 6380 9410 10618
2261 2295 5693 6711 6789 8342 11569 11943 12826 14312
3441 5287 7665 7864 8134 8446 10920 11625 12710 13309
The receiving device/method includes a decoding unit/step for decoding the LDPC code obtained from data transmitted by the transmission method.

In the first receiving device/method of the present technology, the LDPC code obtained from the data transmitted by the first transmission method is decoded.

A second transmission method/apparatus of the present technology includes an encoding step/unit that performs LDPC encoding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 4/16, a group-wise interleaving step/unit that performs group-wise interleaving of the LDPC code in units of 360-bit bit groups, and a mapping step/unit that maps the LDPC code to one of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits, and in the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and a sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
16 32 33 43 3 29 0 22 40 24 44 8 20 13 15 45 7 34 39 42 25 28 18 26 38 10 11 41 47 23 6 1 14 4 12 31 21 19 37 36 30 5 46 27 35 2 9 17
the check matrix includes an A matrix at the top left of the check matrix, which has M1 rows and K columns and is represented by a predetermined value M1 and an information length K=N×r of the LDPC code; a B matrix of a staircase structure adjacent to the right of the A matrix, which has M1 rows and M1 columns; a Z matrix which is a zero matrix adjacent to the right of the B matrix, which has M1 rows and N-K-M1 columns; a C matrix adjacent below the A matrix and the B matrix, which has N-K-M1 rows and K+M1 columns; and a D matrix which is an identity matrix adjacent to the right of the C matrix, which has N-K-M1 rows and N-K-M1 columns; the predetermined value M1 is 1080; the A matrix and the C matrix are represented by a check matrix initial value table, and the check matrix initial value table is a table which represents the positions of elements of 1 in the A matrix and the C matrix for every 360 columns,
159 211 356 1078 1219 1447 1562 2945 4040 4307 7300 11950 12663
163 385 518 669 2137 3537 3738 7393 7668 9235 10263 12293 12959
413 477 747 974 1995 3998 4078 4848 5642 8968 10356 10596 11451
450 538 767 1245 1354 1957 3497 5179 8925 9959 11385 11844
370 381 884 1627 2289 3654 4510 4949 5307 7959 8789 10552
9 146 1045 2160 3696 6477 6509 7297 9854 10704 12493 12533
110 136 327 4780 4841 5818 6642 7015 7594 8053 8882 9916
771 806 928 1281 2049 3065 4006 6536 6818 8041 8548 9357
256 506 939 1176 3954 4207 5143 7352 7620 8473 8534 11045
459 470 916 2393 3302 3371 3572 4732 5492 10845 12327 12767
270 302 754 1105 1430 1916 3788
144 706 1013 7424 7893 9436 10402
1899 3105 11835 12241
1400 7777 10094 10848
8098 10061 10435 12570
The present invention relates to a transmission method/apparatus.

In the second transmission method/apparatus of the present technology, LDPC coding is performed based on a check matrix of an LDPC code with a code length N of 17280 bits and a coding rate r of 4/16, and group-wise interleaving is performed to interleave the LDPC code in units of 360-bit bit groups. Then, the LDPC code is mapped in units of 4 bits to any of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM. In the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
16 32 33 43 3 29 0 22 40 24 44 8 20 13 15 45 7 34 39 42 25 28 18 26 38 10 11 41 47 23 6 1 14 4 12 31 21 19 37 36 30 5 46 27 35 2 9 17
The parity check matrix includes an A matrix at the top left of the parity check matrix, which has M1 rows and K columns and is represented by a predetermined value M1 and an information length K=N×r of the LDPC code, a B matrix of a staircase structure adjacent to the right of the A matrix, which has M1 rows and M1 columns, a Z matrix which is a zero matrix adjacent to the right of the B matrix, which has M1 rows and N-K-M1 columns, a C matrix adjacent below the A matrix and the B matrix, which has N-K-M1 rows and K+M1 columns, and a D matrix which is an identity matrix adjacent to the right of the C matrix, which has N-K-M1 rows and N-K-M1 columns, the predetermined value M1 is 1080, the A matrix and the C matrix are represented by a parity check matrix initial value table, and the parity check matrix initial value table is a table which represents the positions of elements of 1 in the A matrix and the C matrix for every 360 columns,
159 211 356 1078 1219 1447 1562 2945 4040 4307 7300 11950 12663
163 385 518 669 2137 3537 3738 7393 7668 9235 10263 12293 12959
413 477 747 974 1995 3998 4078 4848 5642 8968 10356 10596 11451
450 538 767 1245 1354 1957 3497 5179 8925 9959 11385 11844
370 381 884 1627 2289 3654 4510 4949 5307 7959 8789 10552
9 146 1045 2160 3696 6477 6509 7297 9854 10704 12493 12533
110 136 327 4780 4841 5818 6642 7015 7594 8053 8882 9916
771 806 928 1281 2049 3065 4006 6536 6818 8041 8548 9357
256 506 939 1176 3954 4207 5143 7352 7620 8473 8534 11045
459 470 916 2393 3302 3371 3572 4732 5492 10845 12327 12767
270 302 754 1105 1430 1916 3788
144 706 1013 7424 7893 9436 10402
1899 3105 11835 12241
1400 7777 10094 10848
8098 10061 10435 12570
It has become.

A second receiving device/method of the present technology includes a coding step of performing LDPC coding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 4/16, a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of 360-bit bit groups, and a mapping step of mapping the LDPC code to any of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits, wherein in the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and a sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
16 32 33 43 3 29 0 22 40 24 44 8 20 13 15 45 7 34 39 42 25 28 18 26 38 10 11 41 47 23 6 1 14 4 12 31 21 19 37 36 30 5 46 27 35 2 9 17
the check matrix includes an A matrix at the top left of the check matrix, which has M1 rows and K columns and is represented by a predetermined value M1 and an information length K=N×r of the LDPC code; a B matrix of a staircase structure adjacent to the right of the A matrix, which has M1 rows and M1 columns; a Z matrix which is a zero matrix adjacent to the right of the B matrix, which has M1 rows and N-K-M1 columns; a C matrix adjacent below the A matrix and the B matrix, which has N-K-M1 rows and K+M1 columns; and a D matrix which is an identity matrix adjacent to the right of the C matrix, which has N-K-M1 rows and N-K-M1 columns; the predetermined value M1 is 1080; the A matrix and the C matrix are represented by a check matrix initial value table, and the check matrix initial value table is a table which represents the positions of elements of 1 in the A matrix and the C matrix for every 360 columns,
159 211 356 1078 1219 1447 1562 2945 4040 4307 7300 11950 12663
163 385 518 669 2137 3537 3738 7393 7668 9235 10263 12293 12959
413 477 747 974 1995 3998 4078 4848 5642 8968 10356 10596 11451
450 538 767 1245 1354 1957 3497 5179 8925 9959 11385 11844
370 381 884 1627 2289 3654 4510 4949 5307 7959 8789 10552
9 146 1045 2160 3696 6477 6509 7297 9854 10704 12493 12533
110 136 327 4780 4841 5818 6642 7015 7594 8053 8882 9916
771 806 928 1281 2049 3065 4006 6536 6818 8041 8548 9357
256 506 939 1176 3954 4207 5143 7352 7620 8473 8534 11045
459 470 916 2393 3302 3371 3572 4732 5492 10845 12327 12767
270 302 754 1105 1430 1916 3788
144 706 1013 7424 7893 9436 10402
1899 3105 11835 12241
1400 7777 10094 10848
8098 10061 10435 12570
The receiving device/method includes a decoding unit/step for decoding the LDPC code obtained from data transmitted by the transmission method.

In the second receiving device/method of the present technology, the LDPC code obtained from the data transmitted by the second transmission method is decoded.

A third transmission method/apparatus of the present technology includes an encoding step/unit that performs LDPC encoding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 6/16, a group-wise interleaving step/unit that performs group-wise interleaving of the LDPC code in units of 360-bit bit groups, and a mapping step/unit that maps the LDPC code to one of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits, and in the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and a sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
23 42 33 17 37 2 22 14 21 0 12 44 30 1 25 35 46 13 10 24 20 15 45 31 41 43 28 36 16 4 32 18 3 6 34 11 40 5 38 27 29 8 26 7 39 9 47 19
and interleaving in the order of the above, the parity check matrix includes an A matrix at the top left of the parity check matrix, which has M1 rows and K columns, represented by a predetermined value M1 and an information length K=N×r of the LDPC code, a B matrix of a staircase structure adjacent to the right of the A matrix, which has M1 rows and M1 columns, a Z matrix which is a zero matrix adjacent to the right of the B matrix, which has M1 rows and N-K-M1 columns, a C matrix adjacent below the A matrix and the B matrix, which has N-K-M1 rows and K+M1 columns, and a D matrix which is an identity matrix adjacent to the right of the C matrix, which has N-K-M1 rows and N-K-M1 columns, the predetermined value M1 is 720, the A matrix and the C matrix are represented by a parity check matrix initial value table, and the parity check matrix initial value table is a table that represents the positions of elements of 1 in the A matrix and the C matrix for every 360 columns,
416 437 444 1657 2662 4109 4405 6308 8251
75 498 687 3903 4582 7035 7650 7871 10382
394 419 474 3515 6708 7277 8703 9969 10489
167 289 612 1847 5277 5900 8326 8508 9462
196 439 620 2128 2375 2501 6902 9308 9552
154 495 623 5024 6241 8364 9996 10104 10346
230 329 661 879 1474 3222 4109 8079 8865
97 172 692 1018 1629 1752 3170 5930
359 377 712 6273 7131 7278 8292 10457
368 551 708 787 2891 6140 7195 9555
44 512 655 2196 6692 7975 8410 10727
27 94 611 5585 7258 8091 9867 10714
608 639 691 3560 6819 7492 7754 7916
46 115 214 2175 5986 7177 8589 10757
282 589 604 969 1856 2433 5742 8900
243 262 669 1330 1366 3339 5517 7517
62 392 651 4175 8349 8557 9192 10015
206 375 697 1449 2015 2390 3926 4428 5084 5236 5872 8486 9398 9997 10469
1079 1384 1664 2936 4618 5359 5455 5537 5726 5875 8044 8521 9746
791 1106 1497 1885 2682 3473 3716 4506 5671 5829 8388 8641 9454
The present invention relates to a transmission method/apparatus.

In the third transmission method/apparatus of the present technology, LDPC coding is performed based on a check matrix of an LDPC code with a code length N of 17280 bits and a coding rate r of 6/16, and group-wise interleaving is performed to interleave the LDPC code in units of 360-bit bit groups. Then, the LDPC code is mapped in units of 4 bits to one of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM. In the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
23 42 33 17 37 2 22 14 21 0 12 44 30 1 25 35 46 13 10 24 20 15 45 31 41 43 28 36 16 4 32 18 3 6 34 11 40 5 38 27 29 8 26 7 39 9 47 19
The parity check matrix includes an A matrix at the top left of the parity check matrix, which has M1 rows and K columns and is represented by a predetermined value M1 and an information length K=N×r of the LDPC code, a B matrix of a staircase structure adjacent to the right of the A matrix, which has M1 rows and M1 columns, a Z matrix which is a zero matrix adjacent to the right of the B matrix, which has M1 rows and N-K-M1 columns, a C matrix adjacent below the A matrix and the B matrix, which has N-K-M1 rows and K+M1 columns, and a D matrix which is an identity matrix adjacent to the right of the C matrix, which has N-K-M1 rows and N-K-M1 columns, the predetermined value M1 is 720, the A matrix and the C matrix are represented by a parity check matrix initial value table, and the parity check matrix initial value table is a table which represents the positions of elements of 1 in the A matrix and the C matrix for every 360 columns,
416 437 444 1657 2662 4109 4405 6308 8251
75 498 687 3903 4582 7035 7650 7871 10382
394 419 474 3515 6708 7277 8703 9969 10489
167 289 612 1847 5277 5900 8326 8508 9462
196 439 620 2128 2375 2501 6902 9308 9552
154 495 623 5024 6241 8364 9996 10104 10346
230 329 661 879 1474 3222 4109 8079 8865
97 172 692 1018 1629 1752 3170 5930
359 377 712 6273 7131 7278 8292 10457
368 551 708 787 2891 6140 7195 9555
44 512 655 2196 6692 7975 8410 10727
27 94 611 5585 7258 8091 9867 10714
608 639 691 3560 6819 7492 7754 7916
46 115 214 2175 5986 7177 8589 10757
282 589 604 969 1856 2433 5742 8900
243 262 669 1330 1366 3339 5517 7517
62 392 651 4175 8349 8557 9192 10015
206 375 697 1449 2015 2390 3926 4428 5084 5236 5872 8486 9398 9997 10469
1079 1384 1664 2936 4618 5359 5455 5537 5726 5875 8044 8521 9746
791 1106 1497 1885 2682 3473 3716 4506 5671 5829 8388 8641 9454
It has become.

A third receiving apparatus/method of the present technology includes a coding step of performing LDPC coding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 6/16, a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of 360-bit bit groups, and a mapping step of mapping the LDPC code to any of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits, wherein in the group-wise interleaving, the i+1-th bit group from the beginning of the LDPC code is defined as bit group i, and a sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
23 42 33 17 37 2 22 14 21 0 12 44 30 1 25 35 46 13 10 24 20 15 45 31 41 43 28 36 16 4 32 18 3 6 34 11 40 5 38 27 29 8 26 7 39 9 47 19
and interleaving in the order of the above, the parity check matrix includes an A matrix at the top left of the parity check matrix, which has M1 rows and K columns, represented by a predetermined value M1 and an information length K=N×r of the LDPC code, a B matrix of a staircase structure adjacent to the right of the A matrix, which has M1 rows and M1 columns, a Z matrix which is a zero matrix adjacent to the right of the B matrix, which has M1 rows and N-K-M1 columns, a C matrix adjacent below the A matrix and the B matrix, which has N-K-M1 rows and K+M1 columns, and a D matrix which is an identity matrix adjacent to the right of the C matrix, which has N-K-M1 rows and N-K-M1 columns, the predetermined value M1 is 720, the A matrix and the C matrix are represented by a parity check matrix initial value table, and the parity check matrix initial value table is a table that represents the positions of elements of 1 in the A matrix and the C matrix for every 360 columns,
416 437 444 1657 2662 4109 4405 6308 8251
75 498 687 3903 4582 7035 7650 7871 10382
394 419 474 3515 6708 7277 8703 9969 10489
167 289 612 1847 5277 5900 8326 8508 9462
196 439 620 2128 2375 2501 6902 9308 9552
154 495 623 5024 6241 8364 9996 10104 10346
230 329 661 879 1474 3222 4109 8079 8865
97 172 692 1018 1629 1752 3170 5930
359 377 712 6273 7131 7278 8292 10457
368 551 708 787 2891 6140 7195 9555
44 512 655 2196 6692 7975 8410 10727
27 94 611 5585 7258 8091 9867 10714
608 639 691 3560 6819 7492 7754 7916
46 115 214 2175 5986 7177 8589 10757
282 589 604 969 1856 2433 5742 8900
243 262 669 1330 1366 3339 5517 7517
62 392 651 4175 8349 8557 9192 10015
206 375 697 1449 2015 2390 3926 4428 5084 5236 5872 8486 9398 9997 10469
1079 1384 1664 2936 4618 5359 5455 5537 5726 5875 8044 8521 9746
791 1106 1497 1885 2682 3473 3716 4506 5671 5829 8388 8641 9454
The receiving device/method includes a decoding unit/step for decoding the LDPC code obtained from data transmitted by the transmission method.

In the third receiving device/method of the present technology, the LDPC code obtained from the data transmitted by the third transmission method is decoded.

A fourth transmission method/apparatus of the present technology includes an encoding step/unit that performs LDPC encoding based on a parity check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 8/16, a group-wise interleaving step/unit that performs group-wise interleaving of the LDPC code in units of 360-bit bit groups, and a mapping step/unit that maps the LDPC code to any of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits, and in the group-wise interleaving, a bit group i+1-th bit group from the beginning of the LDPC code is defined as bit group i, and a sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
7 0 8 39 17 3 32 2 13 19 16 14 5 10 27 35 45 26 44 43 11 24 28 34 20 29 22 41 18 9 37 12 21 4 46 33 15 36 42 1 40 25 23 30 6 38 31 47
the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, the check matrix initial value table is a table representing the position of one element of the information matrix portion for every 360 columns,
516 1070 1128 1352 1441 1482 2437 5049 5157 5266 5585 5716 6907 8094
299 4342 4520 4988 5163 5453 5731 5752 6985 7155 8031 8407 8519 8618
178 181 743 814 1188 1313 1384 1769 1838 1930 1968 2123 2487 2497 2829 2852 3220 3245 3936 4054 4358 4397 4482 4514 4567 4711 4785 5217 6030 6747 7127 7254 7845 8552
125 430 594 628 641 740 1895 2007 2148 2363 2790 2920 3158 3493 3768 3805 3896 5067 5103 5121 5292 5764 5857 5948 6338 6523 6578 6880 7303 7557 8242 8371 8387 8634
1631 2139 2453 2544 5442 6255
127 2676 3774 4289 5764 7450
1270 1856 2025 2065 3259 7787
645 1648 5077 6644 6650 8198
485 904 4510
624 4137 7388
724 4865 8587
1247 4729 6266
5604 6147 6898
63 4763 6319
930 6174 7453
981 2960 8486
4286 4304 8058
1460 6205 7561
2339 2998 8002
1824 6660 8286
4264 5378 7779
4145 6343 8515
5007 6959 7845
1853 6196 8289
The present invention relates to a transmission method/apparatus.

In the fourth transmission method/apparatus of the present technology, LDPC coding is performed based on a check matrix of an LDPC code with a code length N of 17280 bits and a coding rate r of 8/16, and group-wise interleaving is performed to interleave the LDPC code in units of 360-bit bit groups. Then, the LDPC code is mapped in units of 4 bits to any of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM. In the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is determined as bit group i.
7 0 8 39 17 3 32 2 13 19 16 14 5 10 27 35 45 26 44 43 11 24 28 34 20 29 22 41 18 9 37 12 21 4 46 33 15 36 42 1 40 25 23 30 6 38 31 47
The LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing the position of an element of the information matrix portion for every 360 columns,
516 1070 1128 1352 1441 1482 2437 5049 5157 5266 5585 5716 6907 8094
299 4342 4520 4988 5163 5453 5731 5752 6985 7155 8031 8407 8519 8618
178 181 743 814 1188 1313 1384 1769 1838 1930 1968 2123 2487 2497 2829 2852 3220 3245 3936 4054 4358 4397 4482 4514 4567 4711 4785 5217 6030 6747 7127 7254 7845 8552
125 430 594 628 641 740 1895 2007 2148 2363 2790 2920 3158 3493 3768 3805 3896 5067 5103 5121 5292 5764 5857 5948 6338 6523 6578 6880 7303 7557 8242 8371 8387 8634
1631 2139 2453 2544 5442 6255
127 2676 3774 4289 5764 7450
1270 1856 2025 2065 3259 7787
645 1648 5077 6644 6650 8198
485 904 4510
624 4137 7388
724 4865 8587
1247 4729 6266
5604 6147 6898
63 4763 6319
930 6174 7453
981 2960 8486
4286 4304 8058
1460 6205 7561
2339 2998 8002
1824 6660 8286
4264 5378 7779
4145 6343 8515
5007 6959 7845
1853 6196 8289
It has become.

A fourth receiving device/method of the present technology includes a coding step of performing LDPC coding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 8/16, a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of 360-bit bit groups, and a mapping step of mapping the LDPC code to any of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits, wherein in the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and a sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
7 0 8 39 17 3 32 2 13 19 16 14 5 10 27 35 45 26 44 43 11 24 28 34 20 29 22 41 18 9 37 12 21 4 46 33 15 36 42 1 40 25 23 30 6 38 31 47
the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, the check matrix initial value table is a table representing the position of one element of the information matrix portion for every 360 columns,
516 1070 1128 1352 1441 1482 2437 5049 5157 5266 5585 5716 6907 8094
299 4342 4520 4988 5163 5453 5731 5752 6985 7155 8031 8407 8519 8618
178 181 743 814 1188 1313 1384 1769 1838 1930 1968 2123 2487 2497 2829 2852 3220 3245 3936 4054 4358 4397 4482 4514 4567 4711 4785 5217 6030 6747 7127 7254 7845 8552
125 430 594 628 641 740 1895 2007 2148 2363 2790 2920 3158 3493 3768 3805 3896 5067 5103 5121 5292 5764 5857 5948 6338 6523 6578 6880 7303 7557 8242 8371 8387 8634
1631 2139 2453 2544 5442 6255
127 2676 3774 4289 5764 7450
1270 1856 2025 2065 3259 7787
645 1648 5077 6644 6650 8198
485 904 4510
624 4137 7388
724 4865 8587
1247 4729 6266
5604 6147 6898
63 4763 6319
930 6174 7453
981 2960 8486
4286 4304 8058
1460 6205 7561
2339 2998 8002
1824 6660 8286
4264 5378 7779
4145 6343 8515
5007 6959 7845
1853 6196 8289
The receiving device/method includes a decoding unit/step for decoding the LDPC code obtained from data transmitted by the transmission method.

In the fourth receiving device/method of the present technology, the LDPC code obtained from the data transmitted by the fourth transmission method is decoded.

A fifth transmission method/apparatus of the present technology includes an encoding step/unit that performs LDPC encoding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 10/16, a group-wise interleaving step/unit that performs group-wise interleaving of the LDPC code in units of 360-bit bit groups, and a mapping step/unit that maps the LDPC code to one of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits, and in the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and a sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
1 28 12 35 23 36 24 17 10 14 15 37 18 13 41 38 33 29 16 21 27 4 9 31 45 40 0 46 7 43 30 34 8 44 47 2 20 6 42 3 22 39 5 32 11 19 25 26
the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, the check matrix initial value table is a table representing the position of one element of the information matrix portion for every 360 columns,
579 608 613 760 795 839 910 1895 2239 2535 2670 2871 3127 3316 3779 3829 3936 4454 4772 4926 6048 6166 6352
263 291 694 1172 1232 1925 2657 3037 3057 3400 3550 3812 4185 4325 5202 5441 5479 5640 5864 5892 6154 6157 6227
527 601 1254 1476 1760 2070 2099 2725 2961 3529 3591 4324 4393 4462 4841 5070 5480 5698 5856 5865 6087 6446
235 319 480 2036 2188 2358 2423 2510 2911 3225 3472 3677 3840 4409 4574 4892 5119 5548 5805 5901 6290 6477
1809 2974 3464 5295 5490 5671
2148 3629 4304 4854 4876 6037
2031 2246 3358 4679 6125 6331
874 2483 2964 3872 4509 4904
4001 4303 5079
1652 4524 5263
2551 3381 5524
713 1908 6304
2722 3347 6201
433 923 5564
2181 4242 6202
51 2711 4435
414 708 5539
2222 5036 5974
784 3588 5125
4256 5004 5540
1761 2781 6037
1547 2266 4377
4109 5836 6337
767 2468 4764
2528 5457 5872
884 4651 4807
161 3582 5164
744 2624 4852
239 1740 5807
33 3595 5121
The present invention relates to a transmission method/apparatus.

In a fifth transmission method/apparatus of the present technology, LDPC coding is performed based on a check matrix of an LDPC code with a code length N of 17280 bits and a coding rate r of 10/16, and group-wise interleaving is performed to interleave the LDPC code in units of 360-bit bit groups. Then, the LDPC code is mapped in units of 4 bits to one of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM. In the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is determined as bit group i.
1 28 12 35 23 36 24 17 10 14 15 37 18 13 41 38 33 29 16 21 27 4 9 31 45 40 0 46 7 43 30 34 8 44 47 2 20 6 42 3 22 39 5 32 11 19 25 26
The LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing the position of an element of the information matrix portion for every 360 columns,
579 608 613 760 795 839 910 1895 2239 2535 2670 2871 3127 3316 3779 3829 3936 4454 4772 4926 6048 6166 6352
263 291 694 1172 1232 1925 2657 3037 3057 3400 3550 3812 4185 4325 5202 5441 5479 5640 5864 5892 6154 6157 6227
527 601 1254 1476 1760 2070 2099 2725 2961 3529 3591 4324 4393 4462 4841 5070 5480 5698 5856 5865 6087 6446
235 319 480 2036 2188 2358 2423 2510 2911 3225 3472 3677 3840 4409 4574 4892 5119 5548 5805 5901 6290 6477
1809 2974 3464 5295 5490 5671
2148 3629 4304 4854 4876 6037
2031 2246 3358 4679 6125 6331
874 2483 2964 3872 4509 4904
4001 4303 5079
1652 4524 5263
2551 3381 5524
713 1908 6304
2722 3347 6201
433 923 5564
2181 4242 6202
51 2711 4435
414 708 5539
2222 5036 5974
784 3588 5125
4256 5004 5540
1761 2781 6037
1547 2266 4377
4109 5836 6337
767 2468 4764
2528 5457 5872
884 4651 4807
161 3582 5164
744 2624 4852
239 1740 5807
33 3595 5121
It has become.

A fifth receiving apparatus/method of the present technology includes a coding step of performing LDPC coding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 10/16, a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of 360-bit bit groups, and a mapping step of mapping the LDPC code to any of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits, wherein in the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and a sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
1 28 12 35 23 36 24 17 10 14 15 37 18 13 41 38 33 29 16 21 27 4 9 31 45 40 0 46 7 43 30 34 8 44 47 2 20 6 42 3 22 39 5 32 11 19 25 26
the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, the check matrix initial value table is a table representing the position of one element of the information matrix portion for every 360 columns,
579 608 613 760 795 839 910 1895 2239 2535 2670 2871 3127 3316 3779 3829 3936 4454 4772 4926 6048 6166 6352
263 291 694 1172 1232 1925 2657 3037 3057 3400 3550 3812 4185 4325 5202 5441 5479 5640 5864 5892 6154 6157 6227
527 601 1254 1476 1760 2070 2099 2725 2961 3529 3591 4324 4393 4462 4841 5070 5480 5698 5856 5865 6087 6446
235 319 480 2036 2188 2358 2423 2510 2911 3225 3472 3677 3840 4409 4574 4892 5119 5548 5805 5901 6290 6477
1809 2974 3464 5295 5490 5671
2148 3629 4304 4854 4876 6037
2031 2246 3358 4679 6125 6331
874 2483 2964 3872 4509 4904
4001 4303 5079
1652 4524 5263
2551 3381 5524
713 1908 6304
2722 3347 6201
433 923 5564
2181 4242 6202
51 2711 4435
414 708 5539
2222 5036 5974
784 3588 5125
4256 5004 5540
1761 2781 6037
1547 2266 4377
4109 5836 6337
767 2468 4764
2528 5457 5872
884 4651 4807
161 3582 5164
744 2624 4852
239 1740 5807
33 3595 5121
The receiving device/method includes a decoding unit/step for decoding the LDPC code obtained from data transmitted by the transmission method.

In the fifth receiving device/method of the present technology, the LDPC code obtained from the data transmitted by the fifth transmission method is decoded.

A sixth transmission method/apparatus of the present technology includes an encoding step/unit that performs LDPC encoding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 12/16, a group-wise interleaving step/unit that performs group-wise interleaving of the LDPC code in units of 360-bit bit groups, and a mapping step/unit that maps the LDPC code to one of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits, and in the group-wise interleaving, a bit group i+1-th bit group from the beginning of the LDPC code is defined as bit group i, and a sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
9 8 3 40 27 4 7 45 28 29 14 41 20 6 21 5 36 12 31 39 30 15 37 10 34 25 1 47 26 13 32 43 44 24 33 16 42 2 22 19 18 35 23 46 11 17 38 0
the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, the check matrix initial value table is a table representing the position of one element of the information matrix portion for every 360 columns,
137 199 292 423 527 694 798 2233 2339 2948 2986 3261 3284 3410 3612 3866 4296
633 691 1035 1038 1250 1476 1885 2332 2871 3064 3186 3785 4114 4205 4213 4280 4291
136 166 369 677 878 1119 1360 1401 1501 1823 1950 2492 2760 2843 3151 3168 3189
23 27 74 90 779 1085 1204 1364 1846 2594 2971 3075 3373 3486 4030 4037 4044
286 789 1412 1513 2388 2407 2725 2757 2790 2839 3111 3227 3292 3596 3665 3710 4147
79 178 389 447 608 625 672 786 965 1258 1605 1677 1816 1910 3027 3815 4292
208 2694 3685
480 770 791
261 3447 3751
1271 2122 3312
134 352 1592
517 1877 2106
173 693 1792
1975 2062 3529
734 1035 1136
546 863 4212
817 2712 3692
415 3771 4305
646 1514 3870
1481 2675 4276
454 2248 2517
1073 1754 2107
1170 1472 3699
841 2243 3804
2485 3636 3894
1961 2302 3591
225 2704 3938
487 1067 3992
2747 3054 3661
2476 2885 3456
242 487 4018
2037 2511 4232
1278 1636 3609
1099 1450 3842
1299 1632 1717
545 4160 4295
The present invention relates to a transmission method/apparatus.

In a sixth transmission method/apparatus of the present technology, LDPC coding is performed based on a check matrix of an LDPC code with a code length N of 17280 bits and a coding rate r of 12/16, and group-wise interleaving is performed to interleave the LDPC code in units of 360-bit bit groups. Then, the LDPC code is mapped in units of 4 bits to one of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM. In the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is determined as bit group i.
9 8 3 40 27 4 7 45 28 29 14 41 20 6 21 5 36 12 31 39 30 15 37 10 34 25 1 47 26 13 32 43 44 24 33 16 42 2 22 19 18 35 23 46 11 17 38 0
The LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing the position of an element of the information matrix portion for every 360 columns,
137 199 292 423 527 694 798 2233 2339 2948 2986 3261 3284 3410 3612 3866 4296
633 691 1035 1038 1250 1476 1885 2332 2871 3064 3186 3785 4114 4205 4213 4280 4291
136 166 369 677 878 1119 1360 1401 1501 1823 1950 2492 2760 2843 3151 3168 3189
23 27 74 90 779 1085 1204 1364 1846 2594 2971 3075 3373 3486 4030 4037 4044
286 789 1412 1513 2388 2407 2725 2757 2790 2839 3111 3227 3292 3596 3665 3710 4147
79 178 389 447 608 625 672 786 965 1258 1605 1677 1816 1910 3027 3815 4292
208 2694 3685
480 770 791
261 3447 3751
1271 2122 3312
134 352 1592
517 1877 2106
173 693 1792
1975 2062 3529
734 1035 1136
546 863 4212
817 2712 3692
415 3771 4305
646 1514 3870
1481 2675 4276
454 2248 2517
1073 1754 2107
1170 1472 3699
841 2243 3804
2485 3636 3894
1961 2302 3591
225 2704 3938
487 1067 3992
2747 3054 3661
2476 2885 3456
242 487 4018
2037 2511 4232
1278 1636 3609
1099 1450 3842
1299 1632 1717
545 4160 4295
It has become.

A sixth receiving apparatus/method of the present technology includes a coding step of performing LDPC coding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 12/16, a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of 360-bit bit groups, and a mapping step of mapping the LDPC code to any of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits, wherein in the group-wise interleaving, the i+1-th bit group from the beginning of the LDPC code is defined as bit group i, and a sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
9 8 3 40 27 4 7 45 28 29 14 41 20 6 21 5 36 12 31 39 30 15 37 10 34 25 1 47 26 13 32 43 44 24 33 16 42 2 22 19 18 35 23 46 11 17 38 0
the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, the check matrix initial value table is a table representing the position of one element of the information matrix portion for every 360 columns,
137 199 292 423 527 694 798 2233 2339 2948 2986 3261 3284 3410 3612 3866 4296
633 691 1035 1038 1250 1476 1885 2332 2871 3064 3186 3785 4114 4205 4213 4280 4291
136 166 369 677 878 1119 1360 1401 1501 1823 1950 2492 2760 2843 3151 3168 3189
23 27 74 90 779 1085 1204 1364 1846 2594 2971 3075 3373 3486 4030 4037 4044
286 789 1412 1513 2388 2407 2725 2757 2790 2839 3111 3227 3292 3596 3665 3710 4147
79 178 389 447 608 625 672 786 965 1258 1605 1677 1816 1910 3027 3815 4292
208 2694 3685
480 770 791
261 3447 3751
1271 2122 3312
134 352 1592
517 1877 2106
173 693 1792
1975 2062 3529
734 1035 1136
546 863 4212
817 2712 3692
415 3771 4305
646 1514 3870
1481 2675 4276
454 2248 2517
1073 1754 2107
1170 1472 3699
841 2243 3804
2485 3636 3894
1961 2302 3591
225 2704 3938
487 1067 3992
2747 3054 3661
2476 2885 3456
242 487 4018
2037 2511 4232
1278 1636 3609
1099 1450 3842
1299 1632 1717
545 4160 4295
The receiving device/method includes a decoding unit/step for decoding the LDPC code obtained from data transmitted by the transmission method.

In the sixth receiving device/method of the present technology, the LDPC code obtained from the data transmitted by the sixth transmission method is decoded.

A seventh transmission method/apparatus of the present technology includes an encoding step/unit that performs LDPC encoding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 14/16, a group-wise interleaving step/unit that performs group-wise interleaving of the LDPC code in units of 360-bit bit groups, and a mapping step/unit that maps the LDPC code to any of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits, and in the group-wise interleaving, a bit group i+1-th bit group from the beginning of the LDPC code is defined as bit group i, and a sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
12 42 40 41 20 18 27 24 39 6 0 15 8 31 10 3 13 46 4 37 33 25 44 2 16 23 28 14 17 43 45 1 35 38 26 21 36 22 47 11 34 29 30 32 19 7 5 9
the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, the check matrix initial value table is a table representing the position of one element of the information matrix portion for every 360 columns,
337 376 447 504 551 864 872 975 1136 1225 1254 1271 1429 1478 1870 2122
58 121 163 365 515 534 855 889 1083 1122 1190 1448 1476 1635 1691 1954
247 342 395 454 479 665 674 1033 1041 1198 1300 1484 1680 1941 2096 2121
80 487 500 513 661 970 1038 1095 1109 1133 1416 1545 1696 1992 2051 2089
32 101 205 413 568 712 714 944 1329 1669 1703 1826 1904 1908 2014 2097
142 201 491 838 860 954 960 965 997 1027 1225 1488 1502 1521 1737 1804
453 1184 1542
10 781 1709
497 903 1546
1080 1640 1861
1198 1616 1817
771 978 2089
369 1079 1348
980 1788 1987
1495 1900 2015
27 540 1070
200 1771 1962
863 988 1329
674 1321 2152
807 1458 1727
844 867 1628
227 546 1027
408 926 1413
361 982 2087
1247 1288 1392
1051 1070 1281
325 452 467
1116 1672 1833
21 236 1267
504 856 2123
398 775 1912
1056 1529 1701
143 930 1186
553 1029 1040
303 653 1308
877 992 1174
1083 1134 1355
298 404 709
970 1272 1799
296 1017 1873
105 780 1418
682 1247 1867
The present invention relates to a transmission method/apparatus.

In the seventh transmission method/apparatus of the present technology, LDPC coding is performed based on a check matrix of an LDPC code with a code length N of 17280 bits and a coding rate r of 14/16, and group-wise interleaving is performed to interleave the LDPC code in units of 360-bit bit groups. Then, the LDPC code is mapped in units of 4 bits to one of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM. In the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is determined as bit group i.
12 42 40 41 20 18 27 24 39 6 0 15 8 31 10 3 13 46 4 37 33 25 44 2 16 23 28 14 17 43 45 1 35 38 26 21 36 22 47 11 34 29 30 32 19 7 5 9
The LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, and the check matrix initial value table is a table representing the position of an element of the information matrix portion for every 360 columns,
337 376 447 504 551 864 872 975 1136 1225 1254 1271 1429 1478 1870 2122
58 121 163 365 515 534 855 889 1083 1122 1190 1448 1476 1635 1691 1954
247 342 395 454 479 665 674 1033 1041 1198 1300 1484 1680 1941 2096 2121
80 487 500 513 661 970 1038 1095 1109 1133 1416 1545 1696 1992 2051 2089
32 101 205 413 568 712 714 944 1329 1669 1703 1826 1904 1908 2014 2097
142 201 491 838 860 954 960 965 997 1027 1225 1488 1502 1521 1737 1804
453 1184 1542
10 781 1709
497 903 1546
1080 1640 1861
1198 1616 1817
771 978 2089
369 1079 1348
980 1788 1987
1495 1900 2015
27 540 1070
200 1771 1962
863 988 1329
674 1321 2152
807 1458 1727
844 867 1628
227 546 1027
408 926 1413
361 982 2087
1247 1288 1392
1051 1070 1281
325 452 467
1116 1672 1833
21 236 1267
504 856 2123
398 775 1912
1056 1529 1701
143 930 1186
553 1029 1040
303 653 1308
877 992 1174
1083 1134 1355
298 404 709
970 1272 1799
296 1017 1873
105 780 1418
682 1247 1867
It has become.

A seventh receiving apparatus/method of the present technology includes a coding step of performing LDPC coding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 14/16, a group-wise interleaving step of performing group-wise interleaving of interleaving the LDPC code in units of 360-bit bit groups, and a mapping step of mapping the LDPC code to any of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits, wherein in the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and a sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group i.
12 42 40 41 20 18 27 24 39 6 0 15 8 31 10 3 13 46 4 37 33 25 44 2 16 23 28 14 17 43 45 1 35 38 26 21 36 22 47 11 34 29 30 32 19 7 5 9
the LDPC code includes information bits and parity bits, the check matrix includes an information matrix portion corresponding to the information bits and a parity matrix portion corresponding to the parity bits, the information matrix portion is represented by a check matrix initial value table, the check matrix initial value table is a table representing the position of one element of the information matrix portion for every 360 columns,
337 376 447 504 551 864 872 975 1136 1225 1254 1271 1429 1478 1870 2122
58 121 163 365 515 534 855 889 1083 1122 1190 1448 1476 1635 1691 1954
247 342 395 454 479 665 674 1033 1041 1198 1300 1484 1680 1941 2096 2121
80 487 500 513 661 970 1038 1095 1109 1133 1416 1545 1696 1992 2051 2089
32 101 205 413 568 712 714 944 1329 1669 1703 1826 1904 1908 2014 2097
142 201 491 838 860 954 960 965 997 1027 1225 1488 1502 1521 1737 1804
453 1184 1542
10 781 1709
497 903 1546
1080 1640 1861
1198 1616 1817
771 978 2089
369 1079 1348
980 1788 1987
1495 1900 2015
27 540 1070
200 1771 1962
863 988 1329
674 1321 2152
807 1458 1727
844 867 1628
227 546 1027
408 926 1413
361 982 2087
1247 1288 1392
1051 1070 1281
325 452 467
1116 1672 1833
21 236 1267
504 856 2123
398 775 1912
1056 1529 1701
143 930 1186
553 1029 1040
303 653 1308
877 992 1174
1083 1134 1355
298 404 709
970 1272 1799
296 1017 1873
105 780 1418
682 1247 1867
The receiving device/method includes a decoding unit/step for decoding the LDPC code obtained from data transmitted by the transmission method.

In the seventh receiving device/method of the present technology, the LDPC code obtained from the data transmitted by the seventh transmission method is decoded.

The transmitting device and receiving device may be independent devices or may be internal blocks that make up a single device.

This technology makes it possible to ensure good communication quality in data transmission using LDPC codes.

The effects described here are not necessarily limited to those described herein, and may be any of the effects described in this disclosure.

FIG. 2 is a diagram illustrating a check matrix H of an LDPC code. 1 is a flowchart illustrating a procedure for decoding an LDPC code. FIG. 2 is a diagram illustrating an example of a check matrix of an LDPC code. FIG. 13 is a diagram illustrating an example of a Tanner graph of a parity check matrix. FIG. 13 is a diagram illustrating an example of a variable node. FIG. 2 is a diagram illustrating an example of a check node. 1 is a diagram illustrating an example of the configuration of an embodiment of a transmission system to which the present technology is applied. 2 is a block diagram showing a configuration example of a transmitting device 11. FIG. 13 is a block diagram showing an example of the configuration of a bit interleaver 116. FIG. FIG. 13 is a diagram illustrating an example of a check matrix. FIG. 13 is a diagram illustrating an example of a parity matrix. 1 is a diagram illustrating a check matrix of an LDPC code defined in the DVB-T.2 standard. 1 is a diagram illustrating a check matrix of an LDPC code defined in the DVB-T.2 standard. FIG. 1 is a diagram illustrating an example of a Tanner graph for decoding an LDPC code. FIG. 1 is a diagram showing an example of a parity matrix H _T having a staircase structure and a Tanner graph corresponding to the parity matrix H _T. 11 is a diagram showing an example of a parity matrix H _T of a check matrix H corresponding to an LDPC code after parity interleaving. FIG. 11 is a flowchart illustrating an example of processing performed by a bit interleaver 116 and a mapper 117. 2 is a block diagram showing an example of the configuration of an LDPC encoder 115. FIG. 11 is a flowchart illustrating an example of a process of the LDPC encoder 115. FIG. 13 is a diagram showing an example of a parity check matrix initial value table with a coding rate of 1/4 and a code length of 16200. 11 is a diagram for explaining a method of obtaining a check matrix H from a check matrix initial value table. FIG. FIG. 2 is a diagram illustrating a structure of a check matrix. FIG. 13 is a diagram illustrating an example of a check matrix initial value table. 13 is a diagram illustrating a matrix A generated from a check matrix initial value table. FIG. FIG. 1 is a diagram for explaining parity interleaving of a B matrix. 11 is a diagram for explaining a C matrix generated from a check matrix initial value table. FIG. FIG. 1 is a diagram for explaining parity interleaving of a D matrix. FIG. 13 is a diagram showing a parity check matrix obtained by performing column permutation as parity deinterleaving to restore parity interleaving to its original state. FIG. 13 is a diagram showing a transformed check matrix obtained by performing row permutation on a check matrix. FIG. 13 is a diagram showing an example of a check matrix initial value table for a Type A code where N=17280 bits and r=2/16. FIG. 11 is a diagram showing an example of a check matrix initial value table for a Type A code where N=17280 bits and r=3/16. FIG. 13 is a diagram showing an example of a check matrix initial value table for a type-A code where N=17280 bits and r=4/16. FIG. 13 is a diagram showing an example of a check matrix initial value table for a type-A code where N=17280 bits and r=5/16. FIG. 13 is a diagram showing an example of a check matrix initial value table for a type-A code where N=17280 bits and r=6/16. FIG. 13 is a diagram illustrating an example of a check matrix initial value table for a type-A code where N=17280 bits and r=7/16. FIG. 13 is a diagram showing an example of a check matrix initial value table for a Type B code where N=17280 bits and r=7/16. FIG. 13 is a diagram showing an example of a check matrix initial value table for a Type B code where N=17280 bits and r=8/16. FIG. 13 is a diagram showing an example of a check matrix initial value table for a Type B code where N=17280 bits and r=9/16. FIG. 13 is a diagram showing an example of a check matrix initial value table for a Type B code where N=17280 bits and r=10/16. FIG. 11 is a diagram showing an example of a check matrix initial value table for a Type B code where N=17280 bits and r=11/16. FIG. 13 is a diagram showing an example of a check matrix initial value table for a Type B code where N=17280 bits and r=12/16. FIG. 13 is a diagram showing an example of a check matrix initial value table for a Type B code where N=17280 bits and r=13/16. FIG. 13 is a diagram showing an example of a check matrix initial value table for a Type B code where N=17280 bits and r=14/16. FIG. 13 is a diagram showing an example of a Tanner graph of an ensemble of degree sequences with column weight 3 and row weight 6. FIG. 13 is a diagram showing an example of a Tanner graph of a multi-edge type ensemble. FIG. 1 is a diagram illustrating a parity check matrix of the Type A method. FIG. 1 is a diagram illustrating a parity check matrix of the Type A method. FIG. 1 is a diagram illustrating a parity check matrix of the Type B method. FIG. 1 is a diagram illustrating a parity check matrix of the Type B method. FIG. 13 is a diagram showing a check matrix initial value table for a new type-A code with N=17280 bits and r=4/16. FIG. 13 is a diagram illustrating parameters of a check matrix H of a new type-A code with r=4/16. FIG. 13 is a diagram showing a check matrix initial value table for the new type-B code with N=17280 bits and r=9/16. FIG. 13 is a diagram showing parameters of a check matrix H of a new type-B code with r=9/16. FIG. 11 is a diagram illustrating an example of coordinates of a UC signal point when the modulation method is QPSK. FIG. 11 is a diagram showing an example of the coordinates of signal points of a 2D-NUC when the modulation method is 16QAM. FIG. 11 is a diagram showing an example of coordinates of signal points of 1D-NUC when the modulation method is 1024QAM. FIG. 1 is a diagram showing the relationship between a 1024QAM symbol y and a position vector u. FIG. 1 is a diagram illustrating an example of coordinates z and _q of signal points of QPSK-UC. FIG. 1 is a diagram illustrating an example of coordinates z and _q of signal points of QPSK-UC. FIG. 1 is a diagram illustrating an example of coordinates z _{and q} of 16QAM-UC signal points. FIG. 1 is a diagram illustrating an example of coordinates z _{and q} of 16QAM-UC signal points. FIG. 13 is a diagram illustrating an example of coordinates z _{and q} of 64QAM-UC signal points. FIG. 13 is a diagram illustrating an example of coordinates z _{and q} of 64QAM-UC signal points. FIG. 13 is a diagram illustrating an example of coordinates z _{and q} of signal points of 256QAM-UC. FIG. 13 is a diagram illustrating an example of coordinates z _{and q} of signal points of 256QAM-UC. FIG. 13 is a diagram illustrating an example of coordinates z _{and q} of 1024QAM-UC signal points. FIG. 13 is a diagram illustrating an example of coordinates z _{and q} of 1024QAM-UC signal points. FIG. 13 is a diagram illustrating an example of coordinates z _{and q} of 4096QAM-UC signal points. FIG. 13 is a diagram illustrating an example of coordinates z _{and q} of 4096QAM-UC signal points. FIG. 13 is a diagram illustrating an example of coordinates _zs of a signal point of 16QAM-2D-NUC. FIG. 13 is a diagram illustrating an example of coordinates _zs of signal points of 64QAM-2D-NUC. FIG. 13 is a diagram illustrating an example of coordinates _zs of signal points of 256QAM-2D-NUC. FIG. 13 is a diagram illustrating an example of coordinates _zs of signal points of 256QAM-2D-NUC. FIG. 11 is a diagram illustrating an example of coordinates _zs of a signal point of 1024QAM-1D-NUC. FIG. 1 is a diagram showing the relationship between a 1024QAM symbol y and a position vector u. FIG. 13 is a diagram illustrating an example of coordinates _zs of a signal point of 4096QAM-1D-NUC. 1 is a diagram showing the relationship between a 4096QAM symbol y and a position vector u. 1 is a diagram showing the relationship between a 4096QAM symbol y and a position vector u. FIG. 2 is a diagram for explaining block interleaving performed by the block interleaver 25. FIG. 2 is a diagram for explaining block interleaving performed by the block interleaver 25. 1 is a diagram illustrating group-wise interleaving performed by group-wise interleaver 24. FIG. FIG. 11 is a diagram showing a first example of a GW pattern for an LDPC code having a code length N of 17280 bits. FIG. 11 is a diagram showing a second example of a GW pattern for an LDPC code having a code length N of 17280 bits. FIG. 11 is a diagram showing a third example of a GW pattern for an LDPC code having a code length N of 17280 bits. FIG. 13 is a diagram showing a fourth example of a GW pattern for an LDPC code having a code length N of 17280 bits. FIG. 5 is a diagram showing a fifth example of a GW pattern for an LDPC code having a code length N of 17280 bits. FIG. 13 is a diagram showing a sixth example of a GW pattern for an LDPC code having a code length N of 17280 bits. FIG. 7 is a diagram showing a seventh example of a GW pattern for an LDPC code having a code length N of 17280 bits. FIG. 13 is a diagram showing an eighth example of a GW pattern for an LDPC code having a code length N of 17280 bits. FIG. 13 is a diagram showing a ninth example of a GW pattern for an LDPC code having a code length N of 17280 bits. FIG. 10 is a diagram showing a tenth example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing an eleventh example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a twelfth example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a thirteenth example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 14th example of a GW pattern for an LDPC code having a code length N of 17280 bits. FIG. 15 is a diagram showing a fifteenth example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 16th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 17th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing an 18th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 19th example of a GW pattern for an LDPC code having a code length N of 17280 bits. FIG. 20 is a diagram showing a twentieth example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 21st example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 22nd example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 23rd example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 24th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 25th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 26th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 27th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 28th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 29th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 30th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 31st example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 32nd example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 33rd example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 34th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 35th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 36th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 37th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing the 38th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 39th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing the 40th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 41st example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 42nd example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 43rd example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing a 44th example of a GW pattern for an LDPC code having a code length N of 17280 bits. A figure showing the 45th example of a GW pattern for an LDPC code having a code length N of 17280 bits. 2 is a block diagram showing an example of the configuration of a receiving device 12. FIG. 13 is a block diagram showing an example of the configuration of a bit deinterleaver 165. FIG. 11 is a flowchart illustrating an example of processing performed by a demapper 164, a bit deinterleaver 165, and an LDPC decoder 166. FIG. 2 is a diagram illustrating an example of a check matrix of an LDPC code. 11 is a diagram showing an example of a matrix (transformed parity check matrix) obtained by performing row permutation and column permutation on a parity check matrix; FIG. FIG. 13 is a diagram showing an example of a transformed check matrix divided into 5×5 units. FIG. 11 is a block diagram showing an example of the configuration of a decoding device that performs P node operations collectively. 13 is a block diagram showing an example of the configuration of an LDPC decoder 166. FIG. FIG. 13 is a diagram for explaining block deinterleaving performed by block deinterleaver 54. 13 is a block diagram showing another example configuration of the bit deinterleaver 165. FIG. 1 is a block diagram showing a first exemplary configuration of a receiving system to which a receiving device 12 can be applied. 11 is a block diagram showing a second exemplary configuration of a receiving system to which the receiving device 12 can be applied. FIG. FIG. 13 is a block diagram showing a third exemplary configuration of a receiving system to which the receiving device 12 can be applied. 1 is a block diagram showing an example of the configuration of an embodiment of a computer to which the present technology is applied.

Below, we will explain the embodiment of this technology, but first we will explain LDPC codes.

<LDPC code>

Note that LDPC codes are linear codes and do not necessarily have to be binary, but here we will explain them as being binary.

The most distinctive feature of LDPC codes is that the parity check matrix that defines them is sparse. Here, a sparse matrix is a matrix with an extremely small number of "1" elements (a matrix with most elements being 0).

Figure 1 shows an example of a check matrix H for an LDPC code.

In the check matrix H in Figure 1, the weight of each column (column weight) (number of "1s") is "3", and the weight of each row (row weight) is "6".

In coding using LDPC codes (LDPC coding), for example, a generator matrix G is generated based on a check matrix H, and then a codeword (LDPC code) is generated by multiplying binary information bits by this generator matrix G.

Specifically, an encoding device that performs LDPC encoding first calculates a generator matrix G such that the equation GH ^T =0 holds between the generator matrix G and a transposed matrix H ^T of a check matrix H. Here, when the generator matrix G is a K×N matrix, the encoding device multiplies the generator matrix G by a bit string (vector u) of K information bits to generate a codeword c (=uG) consisting of N bits. The codeword (LDPC code) generated by this encoding device is received at the receiving side via a predetermined communication path.

Decoding of LDPC codes is an algorithm proposed by Gallager called Probabilistic Decoding, and can be performed by a message passing algorithm using belief propagation on a Tanner graph consisting of variable nodes (also called message nodes) and check nodes. Hereinafter, variable nodes and check nodes will be referred to simply as nodes where appropriate.

Figure 2 is a flowchart showing the procedure for decoding an LDPC code.

In the following description, the real value (received LLR) representing the likelihood of the value of the i-th code bit of the LDPC code (one code word) received by the receiving side being "0" using the log likelihood ratio is also referred to as the received value u _0i . Also, the message output from the check node is u _j , and the message output from the variable node is v _i .

First, in decoding an LDPC code, as shown in Fig. 2, in step S11, an LDPC code is received, a message (check node message) _uj is initialized to "0", and a variable k, which is an integer and serves as a counter for repeated processing, is initialized to "0", and the process proceeds to step S12. In step S12, a message (variable node message) _vj is obtained by performing an operation (variable node operation) shown in formula (1) based on a received value _u0i obtained by receiving the LDPC code, and further, a message _uj is obtained by performing an operation (check node operation) shown in formula (2) based on this message _vj .

・・・（１）

... (1)

・・・（２）

... (2)

Here, _dv and _dc in formula (1) and formula (2) are arbitrarily selectable parameters indicating the number of "1"s in the vertical direction (columns) and horizontal direction (rows), respectively, of the check matrix H. For example, in the case of an LDPC code ((3,6) LDPC code) for a check matrix H having a column _weight of 3 and a _row weight of 6 as shown in FIG.

In the variable node operation of formula (1) and the check node operation of formula (2), messages input from edges (lines connecting variable nodes and check nodes) that are to output messages are not included in the operation, so the operation range is 1 to _dv -1 or 1 to _dc -1. In reality, the check node operation of formula (2) is performed by creating in advance a table of function R( _v1 , _v2 ) shown in formula (3), which is defined as one output for two inputs _v1 and _v2 , and using this continuously (recursively) as shown in formula (4).

・・・（３）

...(3)

・・・（４）

...(4)

In step S12, the variable k is further incremented by "1" and the process proceeds to step S13. In step S13, it is determined whether the variable k is greater than a predetermined number of iterative decoding cycles C. If it is determined in step S13 that the variable k is not greater than C, the process returns to step S12 and the same process is repeated.

Also, if it is determined in step S13 that the variable k is greater than C, the process proceeds to step S14, where the message v _i is calculated as the final decoded result by performing the calculation shown in equation (5) and output, and the decoding process of the LDPC code is completed.

・・・（５）

...(5)

Here, the calculation of equation (5) differs from the variable node calculation of equation (1) in that it is performed using messages u _j from all edges connected to the variable node.

Figure 3 shows an example of a check matrix H for a (3,6) LDPC code (coding rate 1/2, code length 12).

In the check matrix H in Figure 3, the column weight is 3 and the row weight is 6, just like in Figure 1.

Figure 4 shows the Tanner graph of the check matrix H in Figure 3.

In Figure 4, a plus sign "+" indicates a check node, and an equal sign "=" indicates a variable node. The check nodes and variable nodes correspond to the rows and columns of the parity check matrix H, respectively. The connection between the check nodes and variable nodes is an edge, which corresponds to the element "1" of the parity check matrix.

In other words, if the element in the jth row and ith column of the parity check matrix is 1, then in FIG. 4, the i-th variable node from the top (the "=" node) and the j-th check node from the top (the "+" node) are connected by a branch. The branch indicates that the code bit corresponding to the variable node has a constraint corresponding to the check node.

The Sum Product Algorithm, a method for decoding LDPC codes, involves repeated variable node calculations and check node calculations.

Figure 5 shows the variable node calculations performed at the variable node.

In the variable node, the message v _i corresponding to the branch to be calculated is calculated by the variable node calculation of formula (1) using the messages u ₁ and u ₂ from the remaining branches connected to the variable node and the received value u _{0 i} . Messages corresponding to other branches are calculated in the same manner.

Figure 6 shows the check node operations performed at a check node.

The check node operation in formula (2) can be rewritten as formula (6) using the relationship of the formula a×b＝exp{ln(|a|)+ln(|b|)}×sign(a)×sign(b). Note that sign(x) is 1 when x≧0 and -1 when x＜0.

・・・（６）

...(6)

If the function φ(x) is defined as φ(x) = ln(tanh(x/2)) for x≧0, then the equation φ ^-1 (x) = 2tanh ^-1 (e ^-x ) holds, so equation (6) can be transformed into equation (7).

・・・（７）

...(7)

At the check node, the check node operation of equation (2) is performed according to equation (7).

That is, in the check node, as shown in Fig. 6, the message _uj corresponding to the edge to be calculated is obtained by the check node calculation of formula (7) using the messages _v1 , _v2 , _v3 , _v4 , and _v5 from the remaining edges connected to the check node. Messages corresponding to other edges are obtained in the same manner.

The function φ(x) in equation (7) can be expressed as φ(x) = ln((e ^x +1)/(e ^x -1)), where φ(x) = φ ^-1 (x) for x > 0. When implementing the functions φ(x) and φ ^-1 (x) in hardware, they may be implemented using a Look Up Table (LUT), but both of them use the same LUT.

<Example of a transmission system configuration using this technology>

Figure 7 shows an example of the configuration of one embodiment of a transmission system to which the present technology is applied (a system refers to a logical collection of multiple devices, and it does not matter whether the devices are in the same housing or not).

In FIG. 7, the transmission system is composed of a transmitting device 11 and a receiving device 12.

The transmitting device 11 transmits (broadcasts) (transmits), for example, television broadcast programs. That is, the transmitting device 11 encodes the target data to be transmitted, such as image data and audio data as a program, into an LDPC code, and transmits it via a communication path 13, such as a satellite line, terrestrial wave, or cable (wired line).

The receiving device 12 receives the LDPC code transmitted from the transmitting device 11 via the communication path 13, decodes it into the target data, and outputs it.

The LDPC code used in the transmission system in Figure 7 is known to have extremely high performance in AWGN (Additive White Gaussian Noise) communication channels.

On the other hand, burst errors and erasures may occur in the communication path 13. For example, in an OFDM (Orthogonal Frequency Division Multiplexing) system, particularly when the communication path 13 is terrestrial, in a multipath environment where the D/U (Desired to Undesired Ratio) is 0 dB (Undesired = echo power is equal to Desired = main path power), the power of a particular symbol may become 0 (erasure) depending on the delay of the echo (path other than the main path).

Even in a flutter channel (a channel with zero delay and an echo with a Doppler frequency added), if the D/U is 0 dB, the power of the entire OFDM symbol at a specific time may be eradicated due to the Doppler frequency.

Furthermore, burst errors may occur due to the condition of the wiring from a receiving section (not shown) such as an antenna that receives signals from the transmitting device 11 to the receiving device 12, or due to instability in the power supply of the receiving device 12.

On the other hand, in decoding an LDPC code, in the variable nodes corresponding to the columns of the check matrix H, and in turn to the code bits of the LDPC code, as shown in FIG. 5, a variable node operation of the formula (1) involving the addition of the code bits of the LDPC code (received value u _0i ) is performed. Therefore, if an error occurs in the code bits used in the variable node operation, the accuracy of the required message decreases.

In decoding an LDPC code, the check node calculation of equation (7) is performed at a check node using the message obtained at the variable node connected to that check node. Therefore, if there are a large number of check nodes where multiple connected variable nodes (corresponding code bits of the LDPC code) have errors (including erasures) at the same time, the decoding performance deteriorates.

That is, for example, when two or more variable nodes connected to a check node are simultaneously erased, the check node returns to all variable nodes a message with equal probability of the value being 0 and the value being 1. In this case, the check node returning the equally probable message does not contribute to one decoding process (one set of variable node calculations and check node calculations), and as a result, the decoding process needs to be repeated many times, degrading the decoding performance and increasing the power consumption of the receiving device 12 that decodes the LDPC code.

Therefore, the transmission system in Figure 7 is capable of improving tolerance to burst errors and erasures while maintaining performance on an AWGN communication path (AWGN channel).

<Example of the configuration of the transmitting device 11>

Figure 8 is a block diagram showing an example configuration of the transmitting device 11 in Figure 7.

In the transmitting device 11, one or more input streams as target data are supplied to a mode adaptation/multiplexer 111.

The mode adaptation/multiplexer 111 performs processing such as mode selection and multiplexing of one or more input streams supplied to it as necessary, and supplies the resulting data to the padder 112.

The padder 112 performs the necessary zero padding (insertion of nulls) on the data from the mode adaptation/multiplexer 111 and supplies the resulting data to the BB scrambler 113.

The BB scrambler 113 performs BB scrambling (Base-Band Scrambling) on the data from the padder 112 and supplies the resulting data to the BCH encoder 114.

The BCH encoder 114 BCH-encodes the data from the BB scrambler 113 and supplies the resulting data to the LDPC encoder 115 as LDPC target data to be LDPC-encoded.

The LDPC encoder 115 (encoding unit) performs LDPC encoding on the LDPC target data from the BCH encoder 114, for example, according to a check matrix in which the parity matrix, which is the part corresponding to the parity bits of the LDPC code, has a dual diagonal structure, and outputs an LDPC code in which the LDPC target data is information bits.

That is, the LDPC encoder 115 performs LDPC encoding to encode the LDPC target data into an LDPC code (corresponding to a parity check matrix) specified in a specific standard such as DVB-S.2, DVB-T.2, DVB-C.2, or ATSC3.0, or into another LDPC code, and outputs the resulting LDPC code.

The LDPC code specified in the DVB-S.2 and ATSC3.0 standards is an IRA (Irregular Repeat Accumulate) code, and the parity matrix (part or all) in the check matrix of the LDPC code has a staircase structure. The parity matrix and the staircase structure will be described later. The IRA code is described, for example, in "Irregular Repeat-Accumulate Codes," H. Jin, A. Khandekar, and R. J. McEliece, in Proceedings of 2nd International Symposium on Turbo codes and Related Topics, pp. 1-8, Sept. 2000.

The LDPC code output by the LDPC encoder 115 is supplied to the bit interleaver 116.

The bit interleaver 116 performs bit interleaving (described below) on the LDPC code from the LDPC encoder 115, and supplies the bit-interleaved LDPC code to the mapper 117.

The mapper 117 performs orthogonal modulation (multi-level modulation) by mapping the LDPC code from the bit interleaver 116 to a signal point representing one symbol of orthogonal modulation in units of one or more code bits (symbol units) of the LDPC code.

That is, the mapper 117 performs orthogonal modulation by mapping the LDPC code from the bit interleaver 116 to a signal point determined by a modulation method that performs orthogonal modulation of the LDPC code on a constellation that is an IQ plane defined by an I axis representing an I component that is in phase with the carrier wave and a Q axis representing a Q component that is orthogonal to the carrier wave.

When the number of signal points of a constellation used in the modulation method of orthogonal modulation performed in mapper 117 is ^2m , m code bits of the LDPC code are regarded as a symbol (1 symbol), and mapper 117 maps the LDPC code from bit interleaver 116 to a signal point representing a symbol among the ^2m signal points on a symbol-by-symbol basis.

The modulation method of the orthogonal modulation performed by the mapper 117 may be, for example, the modulation method defined in the DVB-S.2 or ATSC3.0 standard, or other modulation methods, such as BPSK (Binary Phase Shift Keying), QPSK (Quadrature Phase Shift Keying), 8PSK (Phase-Shift Keying), 16APSK (Amplitude Phase-Shift Keying), 32APSK, 16QAM (Quadrature Amplitude Modulation), 16QAM, 64QAM, 256QAM, 1024QAM, 4096QAM, 4PAM (Pulse Amplitude Modulation), etc. The modulation method used for the orthogonal modulation in the mapper 117 is preset, for example, according to the operation of the operator of the transmitting device 11.

The data obtained by processing in the mapper 117 (the mapping result of mapping symbols to signal points) is supplied to the time interleaver 118.

The time interleaver 118 performs time interleaving (interleaving in the time direction) on a symbol-by-symbol basis on the data from the mapper 117, and supplies the resulting data to a SISO/MISO (Single Input Single Output/Multiple Input Single Output) encoder 119.

The SISO/MISO encoder 119 performs space-time coding on the data from the time interleaver 118 and supplies it to the frequency interleaver 120.

The frequency interleaver 120 performs frequency interleaving (interleaving in the frequency direction) on a symbol-by-symbol basis on the data from the SISO/MISO encoder 119 and supplies it to the frame builder/resource allocation unit (Frame Builder & Resource Allocation) 131.

On the other hand, the BCH encoder 121 is supplied with control data (signalling) for transmission control, such as BB signaling (Base Band Signalling) (BB Header).

The BCH encoder 121 BCH-encodes the control data supplied thereto in the same manner as the BCH encoder 114, and supplies the resulting data to the LDPC encoder 122.

The LDPC encoder 122 LDPC-encodes the data from the BCH encoder 121 as LDPC target data in the same manner as the LDPC encoder 115, and supplies the resulting LDPC code to the mapper 123.

Similar to mapper 117, mapper 123 performs orthogonal modulation by mapping the LDPC code from LDPC encoder 122 in units of one or more code bits (symbol units) of the LDPC code to a signal point representing one symbol of orthogonal modulation, and supplies the resulting data to frequency interleaver 124.

Similar to the frequency interleaver 120, the frequency interleaver 124 performs frequency interleaving on a symbol-by-symbol basis on the data from the mapper 123 and supplies it to the frame builder/resource allocation unit 131.

The frame builder/resource allocation unit 131 inserts pilot symbols into the necessary positions of the data (symbols) from the frequency interleavers 120 and 124, and constructs a frame consisting of a predetermined number of symbols from the resulting data (symbols) (e.g., a PL (Physical Layer) frame, a T2 frame, a C2 frame, etc.) and supplies it to the OFDM generation unit 132.

The OFDM generation unit 132 generates an OFDM signal corresponding to the frame from the frame builder/resource allocation unit 131 and transmits it via the communication path 13 (Figure 7).

The transmitting device 11 can be configured without some of the blocks shown in FIG. 8, such as the time interleaver 118, the SISO/MISO encoder 119, the frequency interleaver 120, and the frequency interleaver 124.

<Example of the configuration of bit interleaver 116>

Figure 9 is a block diagram showing an example configuration of the bit interleaver 116 in Figure 8.

The bit interleaver 116 has the function of interleaving data, and is composed of a parity interleaver 23, a group-wise interleaver 24, and a block interleaver 25.

The parity interleaver 23 performs parity interleaving to interleave the parity bits of the LDPC code from the LDPC encoder 115 into the positions of other parity bits, and supplies the LDPC code after the parity interleaving to the group-wise interleaver 24.

The group-wise interleaver 24 performs group-wise interleaving on the LDPC code from the parity interleaver 23, and supplies the LDPC code after group-wise interleaving to the block interleaver 25.

In group-wise interleaving, one LDPC code is divided into 360-bit units, equal to the parallel factor P described later, from the beginning of the code, and the 360 bits of each division are treated as bit groups, and the LDPC code from the parity interleaver 23 is interleaved in bit group units.

When group-wise interleaving is performed, the error rate can be improved compared to when group-wise interleaving is not performed, and as a result, good communication quality can be ensured in data transmission.

The block interleaver 25 performs block interleaving to demultiplex the LDPC code from the group-wise interleaver 24, thereby symbolizing, for example, one code's worth of LDPC code into m-bit symbols, which are the unit of mapping, and supplies them to the mapper 117 (Figure 8).

Here, in block interleaving, for example, columns serving as memory areas for storing a predetermined number of bits in the column (vertical) direction are arranged in a number of rows (horizontal) direction equal to the number of bits m of a symbol. The LDPC code from the group-wise interleaver 24 is written in the column direction and read out in the row direction to symbolize the LDPC code into an m-bit symbol.

<LDPC code check matrix>

Figure 10 is a diagram showing an example of a check matrix H used for LDPC encoding in the LDPC encoder 115 of Figure 8.

The check matrix H has an LDGM (Low-Density Generation Matrix) structure, and can be expressed by the equation H = [H _A |H _T ] (a matrix with the elements of the information matrix H _A as the left elements and the elements of the parity matrix H _T as the right elements) using an information matrix H _A of the part of the code bits of the LDPC code corresponding to the information bits and a parity matrix H _T corresponding to the parity bits.

Here, the number of information bits and the number of parity bits among the code bits of one LDPC code (one code word) are called the information length K and the parity length M, respectively, and the number of code bits of one LDPC code (one code word) is called the code length N (= K + M).

The information length K and parity length M for an LDPC code with a certain code length N are determined by the coding rate. Also, the check matrix H is a matrix with M×N rows and N columns. The information matrix H _A is an M×K matrix, and the parity matrix H _T is an M×M matrix.

FIG. 11 is a diagram showing an example of a parity matrix H _T of the check matrix H used for LDPC encoding in the LDPC encoder 115 in FIG.

As the parity matrix H _T of the check matrix H used for LDPC encoding in the LDPC encoder 115, for example, a parity matrix H _T similar to the check matrix H of the LDPC code defined in standards such as DVB-T.2 can be adopted.

The parity matrix H _T of the check matrix H of the LDPC code defined in the standards such as DVB-T.2 is a staircase-structured matrix (lower bidiagonal matrix) in which elements of 1 are arranged in a staircase-like manner, as shown in Fig. 11. The row weight of the parity matrix H _T is 1 for the first row, and 2 for all the remaining rows. The column weight is 1 for the last column, and 2 for all the remaining columns.

As described above, an LDPC code for a check matrix H in which the parity matrix H _T has a staircase structure can be easily generated by using that check matrix H.

That is, an LDPC code (one code word) is represented by row vector c, and the column vector obtained by transposing the row vector is represented by c ^T. In addition, the information bit portion of row vector c, which is the LDPC code, is represented by row vector A, and the parity bit portion is represented by row vector T.

In this case, row vector c can be expressed as c = [A|T] (a row vector with the elements of row vector A as the left elements and row vector T as the right elements) with row vector A as the information bits and row vector T as the parity bits.

Check matrix H and the row vector c=[A|T] as LDPC code must satisfy the formula ^HcT =0. When the parity matrix HT of check matrix H=[H _A |H T] is the staircase structure shown in Fig. 11, the row vector _T as ^the parity bit of the row vector c=[A| _T ] that satisfies this formula ^HcT =0 can be obtained sequentially (in order) by setting the elements of each row to 0 in order from the element of the first row of the column vector ^HcT in formula HcT=0.

Figure 12 is a diagram explaining the check matrix H of the LDPC code defined in standards such as DVB-T.2.

The first KX columns of the check matrix H of the LDPC code defined in standards such as DVB-T.2 have a column weight of X, the next K3 columns have a column weight of 3, the next M-1 columns have a column weight of 2, and the last column has a column weight of 1.

Here, KX+K3+M-1+1 is equal to the code length N.

Figure 13 shows the column numbers KX, K3, and M, as well as the column weight X, for each coding rate r of the LDPC code defined in standards such as DVB-T.2.

Standards such as DVB-T.2 prescribe LDPC codes with code lengths N of 64,800 bits and 16,200 bits.

For an LDPC code with a code length N of 64,800 bits, eleven nominal rates are specified: 1/4, 1/3, 2/5, 1/2, 3/5, 2/3, 3/4, 4/5, 5/6, 8/9, and 9/10. For an LDPC code with a code length N of 16,200 bits, ten nominal rates are specified: 1/4, 1/3, 2/5, 1/2, 3/5, 2/3, 3/4, 4/5, 5/6, and 8/9.

Hereinafter, a code length N of 64,800 bits will also be referred to as 64k bits, and a code length N of 16,200 bits will also be referred to as 16k bits.

For LDPC codes, the code bits corresponding to columns with larger column weights in the check matrix H tend to have lower error rates.

In the check matrix H defined in standards such as DVB-T.2 and shown in Figures 12 and 13, the columns at the beginning (left side) tend to have larger column weights. Therefore, for the LDPC code corresponding to that check matrix H, the code bits at the beginning tend to be more resistant to errors (more resistant to errors), and the code bits at the end tend to be more vulnerable to errors.

＜Parity interleave＞

With reference to Figures 14 to 16, we will explain parity interleaving by the parity interleaver 23 in Figure 9.

Figure 14 shows an example of a Tanner graph (part of it) of a check matrix for an LDPC code.

As shown in Figure 14, when two or more of the variable nodes (corresponding code bits) connected to a check node simultaneously experience an error such as erasure, a check node returns a message to all variable nodes connected to that check node, with equal probability of the value being 0 and the value being 1. For this reason, when multiple variable nodes connected to the same check node simultaneously experience an erasure, etc., decoding performance deteriorates.

Incidentally, the LDPC code output by the LDPC encoder 115 in FIG. 8 is an IRA code, similar to the LDPC code defined in standards such as DVB-T.2, and the parity matrix H _T of the check matrix H has a staircase structure as shown in FIG. 11.

FIG. 15 is a diagram showing an example of the parity matrix H _T having a staircase structure as shown in FIG. 11 and a Tanner graph corresponding to the parity matrix H _T.

FIG. 15A shows an example of a parity matrix H _T having a staircase structure, and FIG. 15B shows a Tanner graph corresponding to the parity matrix H _T of FIG. 15A.

In the parity matrix H _T having a staircase structure, elements of 1 are adjacent in each row (except the first row). Therefore, in the Tanner graph of the parity matrix H _T , two adjacent variable nodes corresponding to columns of two adjacent elements whose value in the parity matrix H _T is 1 are connected to the same check node.

Therefore, when parity bits corresponding to two adjacent variable nodes mentioned above become erroneous at the same time due to a burst error or erasure, the check nodes connected to the two variable nodes (variable nodes that use the parity bits to find a message) corresponding to the two erroneous parity bits return messages with equal probability of being 0 and 1 to the variable node connected to that check node, degrading decoding performance. And when the burst length (the number of consecutive erroneous parity bits) becomes large, the number of check nodes that return messages with equal probability increases, further degrading decoding performance.

To prevent the above-mentioned degradation of decoding performance, the parity interleaver 23 (Figure 9) performs parity interleaving, which interleaves the parity bits of the LDPC code from the LDPC encoder 115 into the positions of other parity bits.

FIG. 16 is a diagram showing a parity matrix H _T of the check matrix H corresponding to the LDPC code after parity interleaving performed by the parity interleaver 23 in FIG.

Here, the information matrix H _A of the check matrix H corresponding to the LDPC code output by the LDPC encoder 115 has a cyclic structure, similar to the information matrix of the check matrix H corresponding to the LDPC code defined in standards such as DVB-T.2.

A cyclic structure is one in which a column is equal to the cyclic shift of another column. For example, it includes a structure in which the position of 1 in each row of each of P columns is cyclically shifted in the column direction by a predetermined value, such as a value proportional to the value q obtained by dividing the first column of P columns by the parity length M. Hereinafter, P columns in a cyclic structure will be referred to as a parallel factor where appropriate.

As explained in Figures 12 and 13, there are two types of LDPC codes defined in standards such as DVB-T.2, with code lengths N of 64,800 bits and 16,200 bits, and for both types of LDPC codes, the parallel factor P is defined as 360, which is one of the divisors of the parity length M excluding 1 and M.

The parity length M is a value other than a prime number expressed by the formula M = q x P = q x 360, with the value q varying depending on the coding rate. Therefore, like the parallel factor P, the value q is another of the divisors of the parity length M, excluding 1 and M, and is obtained by dividing the parity length M by the parallel factor P (the product of P and q, which are divisors of parity length M, is the parity length M).

As described above, the parity interleaver 23 interleaves the K+qx+y+1-th code bit of the code bits of the N-bit LDPC code into the K+Py+x+1-th code bit position as parity interleaving, where K is the information length, x is an integer greater than or equal to 0 and less than P, and y is an integer greater than or equal to 0 and less than q.

The K+qx+y+1th code bit and the K+Py+x+1th code bit are both parity bits because they are code bits after the K+1th bit. Therefore, according to parity interleaving, the position of the parity bit of the LDPC code is moved.

With this type of parity interleaving, variable nodes (corresponding parity bits) connected to the same check node are separated by the parallel factor P, i.e., 360 bits in this case. Therefore, if the burst length is less than 360 bits, it is possible to avoid a situation in which multiple variable nodes connected to the same check node experience an error at the same time, thereby improving resistance to burst errors.

The LDPC code after parity interleaving, in which the K+qx+y+1th code bit is interleaved at the K+Py+x+1th code bit position, matches the LDPC code of the check matrix (hereinafter also referred to as the transformed check matrix) obtained by performing column permutation, in which the K+qx+y+1th column of the original check matrix H is replaced with the K+Py+x+1th column.

In addition, the parity matrix of the converted check matrix has a quasi-cyclic structure with units of P columns (360 columns in FIG. 16), as shown in FIG. 16.

Here, a pseudo-cyclic structure means a structure in which all but a few parts are cyclic.

The transformed check matrix obtained by performing column permutation equivalent to parity interleaving on the check matrix of the LDPC code defined in standards such as DVB-T.2 is missing one element of 1 (and has an element of 0) in the 360 row x 360 column part in the upper right corner of the transformed check matrix (the shift matrix, described below). In that respect, it is not a (completely) cyclic structure, but rather a pseudo-cyclic structure.

The conversion check matrix for the check matrix of the LDPC code output by the LDPC encoder 115 has a quasi-cyclic structure, similar to the conversion check matrix for the check matrix of the LDPC code specified in standards such as DVB-T.2.

The transformed check matrix in FIG. 16 is a matrix in which, in addition to the column permutation equivalent to parity interleaving, row permutation (row permutation) has also been performed on the original check matrix H so that the transformed check matrix is composed of the constituent matrices described below.

Figure 17 is a flowchart explaining the processing performed by the LDPC encoder 115, bit interleaver 116, and mapper 117 in Figure 8.

The LDPC encoder 115 waits for the LDPC target data to be supplied from the BCH encoder 114, and in step S101, encodes the LDPC target data into an LDPC code based on the check matrix, supplies the LDPC code to the bit interleaver 116, and the process proceeds to step S102.

In step S102, the bit interleaver 116 performs bit interleaving on the LDPC code from the LDPC encoder 115, supplies the symbols obtained by the bit interleaving to the mapper 117, and the process proceeds to step S103.

That is, in step S102, in the bit interleaver 116 (FIG. 9), the parity interleaver 23 performs parity interleaving on the LDPC code from the LDPC encoder 115, and supplies the LDPC code after the parity interleaving to the group-wise interleaver 24.

The group-wise interleaver 24 performs group-wise interleaving on the LDPC code from the parity interleaver 23 and supplies it to the block interleaver 25.

The block interleaver 25 performs block interleaving on the LDPC code after group-wise interleaving by the group-wise interleaver 24, and supplies the resulting m-bit symbol to the mapper 117.

In step S103, the mapper 117 performs orthogonal modulation by mapping the symbols from the block interleaver 25 to any of 2 ^m signal points determined by the modulation method of the orthogonal modulation performed by the mapper 117, and supplies the resulting data to the time interleaver 118.

As described above, by performing parity interleaving or group-wise interleaving, it is possible to improve the error rate when multiple code bits of an LDPC code are transmitted as one symbol.

Here, in FIG. 9, for ease of explanation, the parity interleaver 23, which is a block that performs parity interleaving, and the groupwise interleaver 24, which is a block that performs groupwise interleaving, are configured separately, but the parity interleaver 23 and the groupwise interleaver 24 can be configured as an integrated unit.

In other words, both parity interleaving and group-wise interleaving can be performed by writing and reading code bits to memory, and can be represented by a matrix that converts the address at which the code bits are written (write address) into the address at which the code bits are read (read address).

Therefore, if you obtain a matrix by multiplying a matrix representing parity interleaving by a matrix representing group-wise interleaving, you can perform parity interleaving by converting the code bits using these matrices, and then obtain the result of group-wise interleaving the LDPC code after the parity interleaving.

In addition to the parity interleaver 23 and group-wise interleaver 24, the block interleaver 25 can also be configured integrally.

In other words, the block interleaving performed by the block interleaver 25 can also be represented by a matrix that converts the write addresses of the memory that stores the LDPC code into read addresses.

Therefore, if you obtain a matrix by multiplying a matrix representing parity interleaving, a matrix representing group-wise interleaving, and a matrix representing block interleaving, you can use these matrices to perform parity interleaving, group-wise interleaving, and block interleaving all at once.

Note that one or the amount of parity interleaving and group-wise interleaving may not be performed.

<Example of the configuration of the LDPC encoder 115>

Figure 18 is a block diagram showing an example configuration of the LDPC encoder 115 in Figure 8.

The LDPC encoder 122 in FIG. 8 is configured in a similar manner.

As explained in Figures 12 and 13, standards such as DVB-T.2 prescribe LDPC codes with two code lengths N: 64,800 bits and 16,200 bits.

For an LDPC code with a code length N of 64,800 bits, eleven coding rates are specified: 1/4, 1/3, 2/5, 1/2, 3/5, 2/3, 3/4, 4/5, 5/6, 8/9, and 9/10. For an LDPC code with a code length N of 16,200 bits, ten coding rates are specified: 1/4, 1/3, 2/5, 1/2, 3/5, 2/3, 3/4, 4/5, 5/6, and 8/9 (Figures 12 and 13).

The LDPC encoder 115 can perform, for example, encoding (error correction encoding) using LDPC codes with code lengths N of 64,800 bits and 16,200 bits and various coding rates, based on a check matrix H prepared for each code length N and each coding rate.

The LDPC encoder 115 can also perform LDPC encoding based on the check matrix H of an LDPC code with a code length N of 17280 bits or any other code length N and a coding rate r of 2/16, 3/16, 4/16, 5/16, 6/16, 7/16, 8/16, 9/16, 10/16, 11/16, 12/16, 13/16, 14/16, or any other coding rate r.

The LDPC encoder 115 is composed of an encoding processing unit 601 and a memory unit 602.

The encoding processing unit 601 is composed of an encoding rate setting unit 611, an initial value table reading unit 612, a check matrix generation unit 613, an information bit reading unit 614, an encoding parity calculation unit 615, and a control unit 616, and performs LDPC encoding of the LDPC target data supplied to the LDPC encoder 115, and supplies the resulting LDPC code to the bit interleaver 116 (Figure 8).

That is, the coding rate setting unit 611 sets the code length N and coding rate r of the LDPC code, and other specific information that identifies the LDPC code, for example, in response to an operation by an operator.

The initial value table reading unit 612 reads from the memory unit 602 the check matrix initial value table described below, which represents the check matrix of the LDPC code specified by the specific information set by the coding rate setting unit 611.

The check matrix generating unit 613 generates a check matrix H based on the check matrix initial value table read by the initial value table reading unit 612, and stores the check matrix H in the storage unit 602. For example, the check matrix generating unit 613 generates the check matrix H by arranging one element of the information matrix H _A corresponding to the information length K (=code length N-parity length M) according to the code length N and the coding rate r set by the coding rate setting unit 611 in a period of 360 columns (parallel factor P) in the column direction, and stores the check matrix H in the storage unit 602.

The information bit reading unit 614 reads (extracts) information bits of information length K from the LDPC target data supplied to the LDPC encoder 115.

The encoding parity calculation unit 615 reads the check matrix H generated by the check matrix generation unit 613 from the storage unit 602, and uses the check matrix H to calculate parity bits for the information bits read by the information bit reading unit 614 based on a predetermined formula, thereby generating a codeword (LDPC code).

The control unit 616 controls each block that makes up the encoding processing unit 601.

The storage unit 602 stores a plurality of check matrix initial value tables corresponding to the plurality of coding rates shown in FIG. 12 and FIG. 13 for each code length N of 64800 bits, 16200 bits, etc., a check matrix initial value table corresponding to each coding rate of 2/16, 3/16, 4/16, 5/16, 6/16, 7/16, 8/16, 9/16, 10/16, 11/16, 12/16, 13/16, and 14/16 for a code length N of 17280 bits, and other check matrix initial value tables of check matrix H of an LDPC code with an arbitrary code length N and an arbitrary coding rate r. The storage unit 602 also temporarily stores data necessary for the processing of the encoding processing unit 601.

Figure 19 is a flowchart that explains an example of the processing of the LDPC encoder 115 in Figure 18.

In step S201, the coding rate setting unit 611 sets the code length N and coding rate r for LDPC coding, as well as other specific information that identifies the LDPC code.

In step S202, the initial value table reading unit 612 reads from the storage unit 602 a predetermined check matrix initial value table that is specified by the code length N and the coding rate r, etc., as specific information set by the coding rate setting unit 611.

In step S203, the check matrix generation unit 613 uses the check matrix initial value table read from the storage unit 602 by the initial value table reading unit 612 to determine (generate) the check matrix H of the LDPC code having the code length N and coding rate r set by the coding rate setting unit 611, and supplies it to the storage unit 602 for storage.

In step S204, the information bit reading unit 614 reads information bits of information length K (=N×r) corresponding to the code length N and coding rate r set by the coding rate setting unit 611 from the LDPC target data supplied to the LDPC encoder 115, and also reads the check matrix H calculated by the check matrix generation unit 613 from the storage unit 602 and supplies it to the encoding parity calculation unit 615.

In step S205, the encoding parity calculation unit 615 uses the information bits from the information bit reading unit 614 and the check matrix H to sequentially calculate the parity bits of the codeword c that satisfies equation (8).

^HcT = 0
...(8)

In equation (8), c represents a row vector as a codeword (LDPC code), and ^cT represents the transpose of row vector c.

As described above, if the information bit portion of row vector c as an LDPC code (one code word) is represented by row vector A and the parity bit portion is represented by row vector T, row vector c can be expressed as c = [A|T] with row vector A as the information bits and row vector T as the parity bits.

The check matrix H and the row vector c=[A|T] as LDPC code must satisfy the formula ^HcT =0. When the parity matrix HT of the check matrix H=[H _A |H _T ] is the staircase structure shown in Fig. 11, the row vector T as ^the parity bit that constitutes the row vector c=[A| _T ] that satisfies this formula ^HcT =0 can be obtained sequentially by setting the elements of each row to 0, starting from the element of the first row of the column vector ^HcT in the formula HcT=0.

The encoding parity calculation unit 615 calculates the parity bit T for the information bit A from the information bit reading unit 614, and outputs the codeword c = [A | T] represented by the information bit A and the parity bit T as the LDPC encoding result of the information bit A.

Then, in step S206, the control unit 616 determines whether or not to end the LDPC encoding. If it is determined in step S206 that the LDPC encoding is not to end, that is, for example, if there is still LDPC target data to be LDPC encoded, the process returns to step S201 (or step S204), and the processes of steps S201 (or step S204) to S206 are repeated.

Also, if it is determined in step S206 that the LDPC encoding is to be terminated, that is, for example, if there is no LDPC target data to be LDPC encoded, the LDPC encoder 115 terminates the process.

For the LDPC encoder 115, a check matrix initial value table (representing a check matrix) for LDPC codes with various code lengths N and coding rates r can be prepared in advance. The LDPC encoder 115 can perform LDPC encoding into LDPC codes with various code lengths N and coding rates r, using a check matrix H generated from the check matrix initial value table prepared in advance.

<Example of check matrix initial value table>

For example, the check matrix initial value table is a table that represents the position of element 1 of information matrix H _A (Fig. 10) corresponding to the code length N of LDPC code (LDPC code defined by check matrix H) and the information length K according to the coding rate r of check matrix H for each of 360 columns (parallel factor P), and is created in advance for each check matrix H of each code length N and each coding rate r.

That is, the check matrix initial value table indicates at least the positions of elements of 1 in the information matrix H _A for each of 360 columns (parallel factor P).

In addition, the parity check matrix H may be a parity check matrix in which the entire parity matrix H _T has a staircase structure, or a parity check matrix in which a part of the parity matrix H _T has a staircase structure and the remaining part is a diagonal matrix (unit matrix).

Hereinafter, the expression method of the parity check matrix initial value table representing the parity check matrix in which a part of the parity matrix H _T has a staircase structure and the remaining part is a diagonal matrix is also referred to as Type A method. Also, the expression method of the parity check matrix initial value table representing the parity check matrix in which the entire parity matrix H _T has a staircase structure is also referred to as Type B method.

In addition, an LDPC code for a check matrix represented by a Type A check matrix initial value table is also called a Type A code, and an LDPC code for a check matrix represented by a Type B check matrix initial value table is also called a Type B code.

The designations "Type A" and "Type B" conform to the ATSC 3.0 standard. For example, ATSC 3.0 uses both Type A and Type B codes.

Type B coding is used in DVB-T.2 and other formats.

Figure 20 shows an example of a check matrix initial value table for the Type B method.

That is, FIG. 20 shows a check matrix initial value table (representing check matrix H) for a type B code with a code length N of 16200 bits and a coding rate (the coding rate in DVB-T.2 notation) r of 1/4, as specified in the DVB-T.2 standard.

The check matrix generation unit 613 (FIG. 18) uses the check matrix initial value table for the Type B method to find the check matrix H as follows:

Figure 21 is a diagram explaining how to find the check matrix H from the check matrix initial value table for the Type B method.

That is, Figure 21 shows a check matrix initial value table for a Type B code with a code length N of 16200 bits and a coding rate r of 2/3, as specified in the DVB-T.2 standard.

The check matrix initial value table of the Type B method is a table that represents the positions of all elements of 1 in the information matrix H _A corresponding to the information length K according to the code length N and the coding rate r of the LDPC code for each of 360 columns (parallel factor P). In the i-th row, the row numbers of the elements of 1 in the 1+360×(i-1)-th column of the check matrix H (the row numbers of the 1st row of the check matrix H being 0) are arranged in the same number as the column weight of the 1+360×(i-1)-th column.

Here, the parity matrix H _T (FIG. 10) corresponding to the parity length M of the check matrix H of the type B method is determined to have a staircase structure as shown in FIG. 15, so if the information matrix H _A (FIG. 10) corresponding to the information length K can be obtained using the check matrix initial value table, the check matrix H can be obtained.

The number of rows k+1 in the check matrix initial value table for Type B method varies depending on the information length K.

The relationship between the information length K and the number of rows in the check matrix initial value table (k+1) satisfies the following formula (9).

K = (k + 1) x 360
... (9)

Here, 360 in equation (9) is the parallel factor P described in Figure 16.

In the check matrix initial value table in Figure 21, 13 values are listed from the first row to the third row, and 3 values are listed from the fourth row to the k+1th row (the 30th row in Figure 21).

Therefore, the column weight of the check matrix H obtained from the check matrix initial value table in FIG. 21 is 13 from the 1st column to the 1+360×(3-1)-1th column, and 3 from the 1+360×(3-1)th column to the Kth column.

The first row of the parity check matrix initial value table in Figure 21 is 0, 2084, 1613, 1548, 1286, 1460, 3196, 4297, 2481, 3369, 3451, 4620, 2622, which indicates that in the first column of parity check matrix H, the elements of the rows with row numbers 0, 2084, 1613, 1548, 1286, 1460, 3196, 4297, 2481, 3369, 3451, 4620, 2622 are 1 (and the other elements are 0).

In addition, the second row of the parity check matrix initial value table in FIG. 21 is 1,122,1516,3448,2880,1407,1847,3799,3529,373,971,4358,3108, which indicates that in the 361st (=1+360×(2-1))th column of parity check matrix H, the elements of the rows with row numbers 1,122,1516,3448,2880,1407,1847,3799,3529,373,971,4358,3108 are 1.

As described above, the parity check matrix initial value table indicates the positions of elements of 1 in the information matrix H _A of the parity check matrix H for every 360 columns.

Columns other than the 1+360×(i-1)th column of the parity check matrix H, that is, each column from the 2+360×(i-1)th column to the 360×ith column, are arranged by periodically cyclically shifting the element 1 in the 1+360×(i-1)th column determined by the parity check matrix initial value table downward (downward in the column) according to the parity length M.

For example, the 2+360×(i-1)th column is the 1+360×(i-1)th column cyclically shifted downward by M/360(=q), and the next 3+360×(i-1)th column is the 1+360×(i-1)th column cyclically shifted downward by 2×M/360(=2×q) (the 2+360×(i-1)th column cyclically shifted downward by M/360(=q)).

Now, assuming that the numerical value in the i-th row (i-th from the top) and j-th column (j-th from the left) of the parity check matrix initial value table is represented as h _i,j and the row index of the j-th element of 1 in the w-th column of the parity check matrix H is represented as H _wj , the row index H _wj of the element of 1 in the w-th column, which is a column other than the 1+360×(i−1)-th column of the parity check matrix H, can be obtained by equation (10).

H _wj ＝mod( _hi,j ＋mod((w-1),P)×q，M)
...(10)

Here, mod(x, y) means the remainder when x is divided by y.

P is the parallel factor described above, and in this embodiment, it is 360, similar to the standards such as DVB-T.2 and ATSC3.0. Furthermore, q is the value M/360 obtained by dividing the parity length M by the parallel factor P (=360).

The check matrix generation unit 613 (Figure 18) identifies the row number of the element that is 1 in the 1+360×(i-1)th column of the check matrix H using the check matrix initial value table.

Furthermore, the check matrix generation unit 613 (FIG. 18) obtains the row index _Hwj of an element of 1 in the w-th column, which is a column other than the 1+360×(i−1)-th column of the check matrix H, in accordance with equation (10), and generates the check matrix H in which the elements of the row indexes obtained above are set to 1.

Figure 22 shows the structure of check matrix H for Type A.

The check matrix for Type A is composed of matrix A, matrix B, matrix C, matrix D, and matrix Z.

Matrix A is the upper left matrix of check matrix H, with M1 rows and K columns, represented by a predetermined value M1 and the information length K of the LDPC code = code length N × coding rate r.

Matrix B is a step-structured matrix adjacent to the right of matrix A, with M1 rows and M1 columns.

Matrix C is the matrix adjacent to and below matrix A and matrix B, with N-K-M1 rows and K+M1 columns.

The D matrix is an identity matrix with N-K-M1 rows and N-K-M1 columns, adjacent to the right of the C matrix.

The Z matrix is the zero matrix adjacent to the right of the B matrix, with M1 rows and N-K-M1 columns.

In the type A check matrix H, which is composed of the above-mentioned A matrix, D matrix, and Z matrix, the A matrix and a part of the C matrix form the information matrix, and the remaining parts of the B matrix, the C matrix, the D matrix, and the Z matrix form the parity matrix.

Note that matrix B is a staircase-structured matrix and matrix D is a unit matrix, so part of the parity matrix of check matrix H in Type A method (matrix B) has a staircase-structured matrix, and the remaining part (matrix D) is a diagonal matrix (unit matrix).

The A and C matrices, like the information matrix of the parity check matrix H of the Type B method, have a cyclic structure for each column of the parallel factor P (e.g., 360 columns), and the parity check matrix initial value table of the Type A method represents the positions of elements of 1 in the A and C matrices for every 360 columns.

As described above, the A matrix and a part of the C matrix constitute an information matrix, so the Type A method parity check matrix initial value table, which represents the positions of elements of 1 in the A matrix and the C matrix every 360 columns, can be said to at least represent the positions of elements of 1 in the information matrix every 360 columns.

In addition, since the Type A method's parity check matrix initial value table represents the positions of elements that are 1 in the A and C matrices every 360 columns, it can also be said that it represents the positions of elements that are 1 in a part of the parity check matrix (the remaining part of the C matrix) every 360 columns.

Figure 23 shows an example of a check matrix initial value table for the Type A method.

In other words, FIG. 23 shows an example of a check matrix initial value table that represents a check matrix H with a code length N of 35 bits and a coding rate r of 2/7.

The Type A method check matrix initial value table is a table that indicates the positions of elements of 1 in the A and C matrices for each parallel factor P, and in the i-th row, the row numbers of elements of 1 in the 1+P×(i-1)th column of check matrix H (row numbers assuming that the row number of the first row of check matrix H is 0) are listed for the same number of column weights as the 1+P×(i-1)th column.

For simplicity's sake, let's assume that the parallel factor P is, for example, 5.

The parameters of the check matrix H for the Type A method are M1, M2, Q1, and Q2.

M1 (Figure 22) is a parameter that determines the size of the B matrix, and takes a value that is a multiple of the parallel factor P. By adjusting M1, the performance of the LDPC code changes, and it is adjusted to a predetermined value when the check matrix H is determined. Here, it is assumed that M1 is set to 15, which is three times the parallel factor P = 5.

M2 (Figure 22) is the value M-M1 obtained by subtracting M1 from the parity length M.

Here, the information length K is N×r＝35×2/7＝10, and the parity length M is N-K＝35-10＝25, so M2 is M-M1＝25-15＝10.

Q1 is calculated according to the formula Q1 = M1/P and represents the number of cyclic shifts (number of rows) in the A matrix.

In other words, columns other than the 1+P×(i-1)th column of the A matrix of the Type A method check matrix H, that is, each column from the 2+P×(i-1)th column to the P×ith column, are arranged by periodically cyclically shifting the element 1 in the 1+P×(i-1)th column determined by the check matrix initial value table downward (downward in the column), and Q1 represents the number of cyclic shifts in the A matrix.

Q2 is calculated according to the formula Q2 = M2/P and represents the number of cyclic shifts (number of rows) in the C matrix.

In other words, columns other than the 1+P×(i-1)th column of the C matrix of the Type A method check matrix H, that is, each column from the 2+P×(i-1)th column to the P×ith column, are arranged by periodically cyclically shifting the element 1 in the 1+P×(i-1)th column determined by the check matrix initial value table downward (downward in the column), and Q2 represents the number of cyclic shifts in the C matrix.

Here, Q1 is M1/P = 15/5 = 3, and Q2 is M2/P = 10/5 = 2.

In the parity check matrix initial value table of FIG. 23, three numerical values are listed in the first and second rows, and one numerical value is listed in the third to fifth rows. According to this arrangement of numerical values, the column weights of the A and C matrices of the parity check matrix H obtained from the parity check matrix initial value table of FIG. 23 are 3 from the 1=1+5×(1-1)th column to the 10=5×2nd column, and 1 from the 11=1+5×(3-1)th column to the 25=5×5th column.

In other words, the first row of the parity check matrix initial value table in FIG. 23 is 2,6,18, which indicates that in the first column of parity check matrix H, the elements in the row numbers 2,6,18 are 1 (and the other elements are 0).

In this case, the A matrix (Figure 22) is a matrix with 15 rows and 10 columns (M1 rows and K columns), and the C matrix (Figure 22) is a matrix with 10 rows and 25 columns (N-K-M1 rows and K+M1 columns), so the rows with row numbers 0 to 14 of the check matrix H are the rows of the A matrix, and the rows with row numbers 15 to 24 of the check matrix H are the rows of the C matrix.

Therefore, of the rows with row numbers 2, 6, and 18 (hereafter referred to as rows #2, #6, #18, etc.), rows #2 and #6 are rows of the A matrix, and row #18 is a row of the C matrix.

The second row of the parity check matrix initial value table in FIG. 23 is 2, 10, 19, which indicates that the elements of rows #2, #10, and #19 in the 6th (= 1 + 5 × (2-1)) column of parity check matrix H are 1.

Here, in the 6th (=1+5×(2-1)) column of the check matrix H, among rows #2, #10, and #19, rows #2 and #10 are rows of the A matrix, and row #19 is a row of the C matrix.

The third row of the parity check matrix initial value table in Figure 23 is 22, which indicates that the element in row #22 in the 11th (= 1 + 5 × (3-1)) column of parity check matrix H is 1.

Here, in the 11th (= 1 + 5 × (3 - 1)) column of the check matrix H, row #22 is a row of the C matrix.

Similarly, the 19 in the 4th row of the parity check matrix initial value table in FIG. 23 indicates that the element in row #19 in the 16th (= 1 + 5 × (4-1)) column of parity check matrix H is 1, and the 15 in the 5th row of the parity check matrix initial value table in FIG. 23 indicates that the element in row #15 in the 21st (= 1 + 5 × (5-1)) column of parity check matrix H is 1.

As described above, the check matrix initial value table represents the positions of elements of 1 in the A matrix and C matrix of the check matrix H for each parallel factor P = 5 columns.

Columns other than the 1+5×(i-1)th column of the A matrix and C matrix of the parity check matrix H, that is, each column from the 2+5×(i-1)th column to the 5×ith column, are arranged by periodically cyclically shifting the element of 1 in the 1+5×(i-1)th column determined by the parity check matrix initial value table downward (downward in the column direction) according to the parameters Q1 and Q2.

For example, the 2+5×(i-1)th column of matrix A is the 1+5×(i-1)th column cyclically shifted down by Q1 (=3), and the next 3+5×(i-1)th column is the 1+5×(i-1)th column cyclically shifted down by 2×Q1 (=2×3) (the 2+5×(i-1)th column cyclically shifted down by Q1).

For example, the 2+5×(i-1)th column of matrix C is the 1+5×(i-1)th column cyclically shifted down by Q2 (=2), and the next 3+5×(i-1)th column is the 1+5×(i-1)th column cyclically shifted down by 2×Q2 (=2×2) (the 2+5×(i-1)th column cyclically shifted down by Q2).

Figure 24 shows the A matrix generated from the check matrix initial value table in Figure 23.

In matrix A in FIG. 24, the elements in rows #2 and #6 of the 1st (= 1 + 5 × (1-1)) column are 1, in accordance with the 1st row of the parity check matrix initial value table in FIG. 23.

And each column from the 2nd (=2+5×(1-1)) to the 5th (=5+5×(1-1)) columns is a cyclic shift of Q1=3 downwards from the previous column.

Furthermore, in matrix A in FIG. 24, the elements in rows #2 and #10 of the 6th (= 1 + 5 × (2-1)) column are 1, in accordance with the second row of the parity check matrix initial value table in FIG. 23.

And each column from the 7th (= 2 + 5 × (2-1)) to the 10th (= 5 + 5 × (2-1)) columns is a cyclic shift of Q1 = 3 downwards from the previous column.

Figure 25 shows the parity interleaving of the B matrix.

The check matrix generation unit 613 (Figure 18) uses the check matrix initial value table to generate matrix A, and places matrix B of a staircase structure to the immediate right of matrix A. Then, the check matrix generation unit 613 regards matrix B as a parity matrix, and performs parity interleaving so that adjacent elements of 1 in matrix B of the staircase structure are separated in the row direction by a parallel factor P = 5.

Figure 25 shows the A and B matrices after parity interleaving of the B matrix in Figure 24.

Figure 26 shows the C matrix generated from the check matrix initial value table in Figure 23.

In matrix C in FIG. 26, the element in row #18 of the 1st (= 1 + 5 × (1 - 1))th column of parity check matrix H is 1, in accordance with the 1st row of the parity check matrix initial value table in FIG. 23.

And each column from the 2nd (=2+5×(1-1)) to the 5th (=5+5×(1-1)) of the C matrix is a cyclic shift of the previous column downwards by Q2=2.

Furthermore, in matrix C of FIG. 26, in accordance with the second to fifth rows of the parity check matrix initial value table of FIG. 23, the elements of row #19 in the 6th (=1+5×(2-1)) column, row #22 in the 11th (=1+5×(3-1)) column, row #19 in the 16th (=1+5×(4-1)) column, and row #15 in the 21st (=1+5×(5-1)) column of parity check matrix H are set to 1.

And each column from 7 (=2+5×(2-1)) to 10 (=5+5×(2-1)), each column from 12 (=2+5×(3-1)) to 15 (=5+5×(3-1)), each column from 17 (=2+5×(4-1)) to 20 (=5+5×(4-1)), and each column from 22 (=2+5×(5-1)) to 25 (=5+5×(5-1)) are cyclically shifted downwards by Q2=2 from the previous column.

The check matrix generation unit 613 (Figure 18) uses the check matrix initial value table to generate matrix C, and places matrix C below matrix A and matrix B (after parity interleaving).

Furthermore, the check matrix generation unit 613 places the Z matrix to the right of the B matrix, and places the D matrix to the right of the C matrix, generating the check matrix H shown in FIG. 26.

Figure 27 shows the parity interleaving of the D matrix.

After generating the check matrix H in FIG. 26, the check matrix generation unit 613 regards the D matrix as a parity matrix and performs parity interleaving (only on the D matrix) so that elements with a value of 1 in an odd row and the next even row of the unit matrix D matrix are separated in the row direction by a parallel factor P = 5.

Figure 27 shows the check matrix H after performing parity interleaving of the D matrix on the check matrix H in Figure 26.

The LDPC encoder 115 (the encoding parity calculation unit 615 (Figure 18)) performs LDPC encoding (generation of LDPC code) using, for example, the check matrix H in Figure 27.

The LDPC code generated using the check matrix H in FIG. 27 is an LDPC code that has been parity interleaved, and therefore, for the LDPC code generated using the check matrix H in FIG. 27, there is no need to perform parity interleaving in the parity interleaver 23 (FIG. 9). In other words, the LDPC code generated using the check matrix H after parity interleaving of the D matrix is an LDPC code that has been parity interleaved, and therefore, for such an LDPC code, the parity interleaving in the parity interleaver 23 is skipped.

Figure 28 shows the parity check matrix H in Figure 27, where column permutation has been performed on the B matrix, part of the C matrix (the part of the C matrix that is placed under the B matrix), and the D matrix as parity deinterleaving to restore the parity interleaving.

The LDPC encoder 115 can perform LDPC encoding (generation of an LDPC code) using the check matrix H in FIG. 28.

When LDPC coding is performed using the check matrix H in FIG. 28, an LDPC code that does not undergo parity interleaving is obtained. Therefore, when LDPC coding is performed using the check matrix H in FIG. 28, parity interleaving is performed in the parity interleaver 23 (FIG. 9).

Figure 29 shows the converted check matrix H obtained by performing row permutation on the check matrix H in Figure 27.

As described below, the conversion check matrix is a matrix that is expressed by a combination of a P×P unit matrix, a quasi-unit matrix in which one or more of the 1's in the unit matrix are replaced with 0, a shift matrix obtained by cyclically shifting a unit matrix or a quasi-unit matrix, a sum matrix that is the sum of two or more of the unit matrix, the quasi-unit matrix, or the shift matrix, and a P×P 0 matrix.

By using the conversion check matrix for decoding the LDPC code, it is possible to adopt an architecture for simultaneously performing P check node operations and variable node operations in the decoding of the LDPC code, as described below.

<New LDPC code>

One way to ensure good communication quality in data transmission using LDPC codes is to use high-performance LDPC codes.

Below, we explain a new LDPC code with good performance (hereafter referred to as the new LDPC code).

As a new LDPC code, for example, a type A code or type B code can be adopted in which the parallel factor P is 360, the same as in DVB-T.2, ATSC3.0, etc., and the check matrix H has a cyclic structure.

The LDPC encoder 115 (FIGS. 8 and 18) can perform LDPC encoding into an LDPC code using a check matrix initial value table (or a check matrix H obtained from) for an LDPC code in which the code length N is longer than 64 kbits, e.g., 69120 bits, and the coding rate r is, e.g., 2/16, 3/16, 4/16, 5/16, 6/16, 7/16, 8/16, 9/16, 10/16, 11/16, 12/16, 13/16, or 14/16.

The LDPC encoder 115 can also perform LDPC encoding into a new LDPC code based on a check matrix H obtained from a check matrix initial value table for a new LDPC code in which the code length N is shorter than 64 kbits, for example, 17280 bits (17 kbits), and the coding rate r is, for example, 2/16, 3/16, 4/16, 5/16, 6/16, 7/16, 8/16, 9/16, 10/16, 11/16, 12/16, 13/16, or 14/16.

When LDPC encoding is performed to a new LDPC code with a code length N of 17,280 bits, a check matrix initial value table for the new LDPC code is stored in the memory unit 602 of the LDPC encoder 115 (Figure 8).

Figure 30 shows an example of a check matrix initial value table (for the Type A method) that represents the check matrix H of a Type A code (hereinafter also referred to as a Type A code with r=2/16) as a new LDPC code with a code length N of 17280 bits and a coding rate r of 2/16.

Figure 31 is a diagram showing an example of a check matrix initial value table that represents the check matrix H of a type A code (hereinafter also referred to as a type A code with r = 3/16) as a new LDPC code with a code length N of 17280 bits and a coding rate r of 3/16.

Figure 32 is a diagram showing an example of a check matrix initial value table that represents the check matrix H of a type A code (hereinafter also referred to as a type A code with r = 4/16) as a new LDPC code with a code length N of 17280 bits and a coding rate r of 4/16.

Figure 33 is a diagram showing an example of a check matrix initial value table that represents the check matrix H of a type A code (hereinafter also referred to as a type A code with r = 5/16) as a new LDPC code with a code length N of 17280 bits and a coding rate r of 5/16.

Figure 34 is a diagram showing an example of a check matrix initial value table that represents the check matrix H of a type A code (hereinafter also referred to as a type A code with r = 6/16) as a new LDPC code with a code length N of 17280 bits and a coding rate r of 6/16.

Figure 35 is a diagram showing an example of a check matrix initial value table that represents the check matrix H of a type A code (hereinafter also referred to as a type A code with r = 7/16) as a new LDPC code with a code length N of 17280 bits and a coding rate r of 7/16.

Figure 36 is a diagram showing an example of a check matrix initial value table (for the Type B method) that represents the check matrix H of a Type B code (hereinafter also referred to as a Type B code with r=7/16) as a new LDPC code with a code length N of 17280 bits and a coding rate r of 7/16.

Figure 37 is a diagram showing an example of a check matrix initial value table that represents the check matrix H of a type B code (hereinafter also referred to as a type B code with r = 8/16) as a new LDPC code with a code length N of 17280 bits and a coding rate r of 8/16.

Figure 38 shows an example of a check matrix initial value table that represents the check matrix H of a type B code (hereinafter also referred to as a type B code with r = 9/16) as a new LDPC code with a code length N of 17280 bits and a coding rate r of 9/16.

Figure 39 is a diagram showing an example of a check matrix initial value table that represents the check matrix H of a type B code (hereinafter also referred to as a type B code with r = 10/16) as a new LDPC code with a code length N of 17280 bits and a coding rate r of 10/16.

Figure 40 shows an example of a check matrix initial value table that represents the check matrix H of a type B code (hereinafter also referred to as a type B code with r = 11/16) as a new LDPC code with a code length N of 17280 bits and a coding rate r of 11/16.

Figure 41 shows an example of a check matrix initial value table that represents the check matrix H of a type B code (hereinafter also referred to as a type B code with r = 12/16) as a new LDPC code with a code length N of 17280 bits and a coding rate r of 12/16.

Figure 42 shows an example of a check matrix initial value table that represents the check matrix H of a type B code (hereinafter also referred to as a type B code with r = 13/16) as a new LDPC code with a code length N of 17280 bits and a coding rate r of 13/16.

Figure 43 shows an example of a check matrix initial value table that represents the check matrix H of a type B code (hereinafter also referred to as a type B code with r = 14/16) as a new LDPC code with a code length N of 17280 bits and a coding rate r of 14/16.

The new LDPC code is a high-performance LDPC code.

Here, a high-performance LDPC code is one that is obtained from an appropriate check matrix H.

An appropriate check matrix H is, for example, a check matrix that satisfies a predetermined condition and reduces the bit error rate ( _BER ) (and frame error rate (FER)) when the LDPC code obtained from the check matrix H is transmitted at a low E s /N ₀ or E _b /N _o (signal power to noise power ratio per bit).

An appropriate check matrix H can be found, for example, by performing a simulation to measure the BER when LDPC codes obtained from various check matrices that satisfy predetermined conditions are transmitted at a low E _s /N _o .

The predetermined conditions that an appropriate check matrix H must satisfy include, for example, good analytical results obtained by a method for analyzing the performance of the code called Density Evolution, and the absence of a loop of elements of 1, called cycle 4.

Here, it is known that if elements of 1 are concentrated in the information matrix H _A , such as in cycle 4, the decoding performance of the LDPC code deteriorates. For this reason, it is desirable that cycle 4 does not exist in the check matrix H.

In the check matrix H, the minimum length of a loop made up of elements of 1 is called the girth. The absence of cycle 4 means that the girth is greater than 4.

The predetermined conditions that an appropriate check matrix H must satisfy can be determined appropriately from the viewpoint of improving the decoding performance of the LDPC code, facilitating (simplifying) the decoding process of the LDPC code, etc.

Figures 44 and 45 are diagrams explaining density evolution that obtains analysis results as predetermined conditions that an appropriate check matrix H must satisfy.

Density evolution is a code analysis method that calculates the expected error probability for an ensemble of LDPC codes with code length N of ∞, characterized by a degree sequence (described below).

For example, in an AWGN channel, if the noise variance is increased from 0, the expected error probability of a certain ensemble is initially 0, but once the noise variance exceeds a certain threshold, it is no longer 0.

According to density evolution, the performance of the ensemble (the appropriateness of the check matrix) can be determined by comparing the noise variance threshold (hereafter referred to as the performance threshold) at which the expected value of the error probability is no longer zero.

For a specific LDPC code, by determining the ensemble to which the LDPC code belongs and performing density evolution on that ensemble, it is possible to predict the rough performance of the LDPC code.

Therefore, if you find an ensemble with good performance, you can find a good LDPC code among the LDPC codes that belong to that ensemble.

The degree sequence mentioned above indicates the proportion of variable nodes and check nodes with each weight value for the code length N of the LDPC code.

For example, a regular(3,6) LDPC code with a code rate of 1/2 belongs to an ensemble characterized by a degree sequence in which all variable nodes have a weight (column weight) of 3 and all check nodes have a weight (row weight) of 6.

Figure 44 shows the Tanner graph of such an ensemble.

In the Tanner Bluff of Figure 44, there are N variable nodes, indicated by circles (○) in the figure, which is equal to the code length N, and there are N/2 check nodes, indicated by squares (□) in the figure, which is equal to the product of the code length N and the coding rate 1/2.

Each variable node has three edges connected to it, equal to the column weight, so there are a total of 3N edges connecting the N variable nodes.

Also, each check node has 6 edges connected to it, equal to the row weight, so there are a total of 3N edges connecting to the N/2 check nodes.

Furthermore, in the Tanner graph of Figure 44, there is one interleaver.

The interleaver randomly rearranges the 3N branches connected to the N variable nodes, and then connects each rearranged branch to one of the 3N branches connected to the N/2 check nodes.

There are only (3N)! (= (3N) x (3N-1) x ... x 1) possible permutations for the 3N branches connected to N variable nodes in an interleaver. Therefore, an ensemble characterized by a degree sequence in which all variable nodes have a weight of 3 and all check nodes have a weight of 6 is a set of (3N)! LDPC codes.

In a simulation to find a high-performance LDPC code (appropriate check matrix), a multi-edge type ensemble was used in density evolution.

In the multi-edge type, the interleaver through which the branches connected to the variable nodes and the branches connected to the check nodes pass is divided into multiple (multi-edge), which allows for more precise characterization of the ensemble.

Figure 45 shows an example of a Tanner graph for a multi-edge type ensemble.

In the Tanner graph of Figure 45, there are two interleavers: a first interleaver and a second interleaver.

In addition, in the Tanner graph of Figure 45, there are only v1 variable nodes with one edge connected to the first interleaver and zero edges connected to the second interleaver, only v2 variable nodes with one edge connected to the first interleaver and two edges connected to the second interleaver, and only v3 variable nodes with zero edges connected to the first interleaver and two edges connected to the second interleaver.

Furthermore, in the Tanner graph of Figure 45, there are c1 check nodes with 2 edges connected to the first interleaver and 0 edges connected to the second interleaver, c2 check nodes with 2 edges connected to the first interleaver and 2 edges connected to the second interleaver, and c3 check nodes with 0 edges connected to the first interleaver and 3 edges connected to the second interleaver.

Here, density evolution and its implementation are described, for example, in "On the Design of Low-Density Parity-Check Codes within 0.0045 dB of the Shannon Limit", S.Y.Chung, G.D.Forney, T.J.Richardson,R.Urbanke, IEEE Communications Leggers, VOL.5, NO.2, Feb 2001.

In a simulation to find a new LDPC code (its check matrix), an ensemble was found where the performance threshold, E _b /N ₀ (signal power to noise power ratio per bit) at which the BER begins to drop (become smaller) is below a specified value using multi-edge type density evolution, and from among the LDPC codes belonging to that ensemble, the LDPC code that reduces the BER when using one or more orthogonal modulation methods such as QPSK was selected as the LDPC code with good performance.

The new LDPC code (the check matrix initial value table that represents the check matrix) was obtained through the above simulations.

Therefore, the new LDPC code can ensure good communication quality in data transmission.

Figure 46 is a diagram explaining the column weights of the check matrix H of a type A code as a new LDPC code.

As shown in Figure 46, for the check matrix H of the type A code, the column weight of the first K1 columns of the A matrix and the C matrix is represented as X1, the column weight of the subsequent K2 columns of the A matrix and the C matrix is represented as X2, the column weight of the further subsequent K3 columns of the A matrix and the C matrix is represented as X3, and the column weight of the further subsequent M1 columns of the C matrix is represented as XM1.

Note that K1+K2+K3 is equal to the information length K, and M1+M2 is equal to the parity length M. Therefore, K1+K2+K3+M1+M2 is equal to the code length N=17280 bits.

For the check matrix H of the type A code, the column weight of the 1st column to the M1-1th column of the B matrix is 2, and the column weight of the M1th column (the last column) of the B matrix is 1. Furthermore, the column weight of the D matrix is 1, and the column weight of the Z matrix is 0.

Figure 47 shows the parameters of the check matrix H of the type A code (represented by the check matrix initial value table) in Figures 30 to 35.

The parameters K, X1, K1, X2, K2, X3, K3, XM1, M1, and M2 of the check matrix H for type A code with r=2/16, 3/16, 4/16, 5/16, 6/16, and 7/16 are as shown in Figure 47.

The parameters X1, K1, X2, K2, X3, K3, XM1, and M1 (or M2) are set to further improve the performance (e.g., error rate, etc.) of the LDPC code.

Figure 48 is a diagram explaining the column weights of the check matrix H of a Type B code as a new LDPC code.

As for the check matrix H of a Type B code, as shown in FIG. 48, the column weight of the first to last KX1 columns is represented as X1, the column weight of the subsequent KX2 column is represented as X2, the column weight of the subsequent KX3 column is represented as X3, the column weight of the subsequent KX4 column is represented as X4, and the column weight of the subsequent KY1 column is represented as Y1.

Note that KX1+KX2+KX3+KX4+KY1 is equal to the information length K, and KX1+KX2+KX3+KX4+KY1+M is equal to the code length N=17280 bits.

In addition, for the check matrix H of a type B code, the column weight of the last M columns, excluding the last column, is 2, and the column weight of the last column is 1.

Figure 49 shows the parameters of the check matrix H of the type B code (represented by the check matrix initial value table) in Figures 36 to 43.

The parameters K, X1, KX1, X2, KX2, X3, KX3, X4, KX4, Y1, KY1, and M of the check matrix H for type B code with r=7/16, 8/16, 9/16, 10/16, 11/16, 12/16, 13/16, and 14/16 are as shown in Figure 49.

The parameters X1, KX1, X2, KX2, X3, KX3, X4, KX4, Y1, and KY1 are set to further improve the performance of the LDPC code.

The new LDPC code achieves good BER/FER and a capacity (channel capacity) close to the Shannon limit.

Figures 50 to 53 are diagrams explaining other examples of new LDPC codes.

That is, FIG. 50 is a diagram showing an example of a check matrix initial value table that represents the check matrix H of a type A code (hereinafter also referred to as a new type A code with r=4/16) provided by the Japan Broadcasting Corporation as a new LDPC code with a code length N of 17280 bits and a coding rate r of 4/16.

Figure 51 shows the parameters of the check matrix H for the new Type A code with r=7/16 provided by the Japan Broadcasting Corporation.

The parameters K, X1, K1, X2, K2, X3, K3, XM1, M1, and M2 are the parameters explained in FIG. 46, and the parameters K, X1, K1, X2, K2, X3, K3, XM1, M1, and M2 of the check matrix H of the new type A code with r=4/16 are as shown in FIG. 51.

Figure 52 shows an example of a check matrix initial value table that represents the check matrix H of a type B code (hereinafter also referred to as a new type B code with r = 9/16) provided by the Japan Broadcasting Corporation as a new LDPC code with a code length N of 17280 bits and a coding rate r of 9/16.

Figure 53 shows the parameters of the check matrix H for the new type B code with r=9/16 provided by the Japan Broadcasting Corporation.

The parameters K, X1, KX1, X2, KX2, X3, KX3, X4, KX4, Y1, KY1, and M are the parameters explained in FIG. 48, and the parameters K, X1, KX1, X2, KX2, X3, KX3, X4, KX4, Y1, KY1, and M of the check matrix H of the new type B code with r=9/16 are as shown in FIG. 52.

<Constellation>

Figures 54 to 78 show examples of constellations that can be used in the transmission system of Figure 7.

In the transmission system of Figure 7, for example, for MODCOD, which is a combination of a modulation method (MODulation) and an LDPC code (CODe), it is possible to set a constellation to be used for that MODCOD.

For a MODCOD of 1, one or more constellations can be set.

There are two types of constellations: UC (Uniform Constellation), in which the signal points are arranged uniformly, and NUC (Non Uniform Constellation), in which the signal points are not arranged uniformly.

Furthermore, NUC includes, for example, a constellation called 1D-NUC (1-dimensional (M ² -QAM) non-uniform constellation) and a constellation called 2D-NUC (2-dimensional (QQAM) non-uniform constellation).

In general, BER is improved with 1D-NUC compared to UC, and BER is further improved with 2D-NUC compared to 1D-NUC.

The constellation when the modulation method is QPSK is UC. For example, UC or 2D-NUC can be used as a constellation when the modulation method is 16QAM, 64QAM, 256QAM, etc., and for example, UC or 1D-NUC can be used as a constellation when the modulation method is 1024QAM, 4096QAM, etc.

The transmission system in Figure 7 can use various constellations that improve error rates, such as those specified in ATSC3.0 and DVB-C.2.

That is, when the modulation method is QPSK, for example, the same UC can be used for each coding rate r of the LDPC code.

In addition, when the modulation method is 16QAM, 64QAM, or 256QAM, for example, the same UC can be used for each coding rate r of the LDPC code. Furthermore, when the modulation method is 16QAM, 64QAM, or 256QAM, for example, a different 2D-NUC can be used for each coding rate r of the LDPC code.

In addition, when the modulation method is 1024QAM or 4096QAM, for example, the same UC can be used for each coding rate r of the LDPC code. Furthermore, when the modulation method is 1024QAM or 4096QAM, for example, a different 1D-NUC can be used for each coding rate r of the LDPC code.

Here, UC of QPSK is also referred to as QPSK-UC, UC of 2 ^{m QAM is also referred to as 2 m QAM-UC, and 1D-NUC and 2D-NUC of 2 m QAM} are also referred to as 2 ^m QAM-1D-NUC and 2 ^m QAM-2D-NUC, respectively.

Below, we will explain some of the constellations defined in ATSC3.0.

Figure 54 shows the coordinates of QPSK-UC signal points used for all coding rates of LDPC codes specified in ATSC3.0 when the modulation method is QPSK.

In Fig.54, "Input Data cell y" represents a 2-bit symbol to be mapped to QPSK-UC, and "Constellation point _zs " represents the coordinates of constellation point _zs . Note that index s of constellation point _zs (as well as index q of constellation point _zq , described later) represents the discrete time of the symbol (the time interval between one symbol and the next symbol).

In FIG. 54, the coordinates of the signal point _zs are expressed in the form of complex numbers, and j represents the imaginary unit (√(-1)).

Figure 55 shows the coordinates of the signal points of 16QAM-2D-NUC used for the coding rates r(CR) = 2/15, 3/15, 4/15, 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12,15, 13/15 of the LDPC code specified in ATSC3.0 when the modulation method is 16QAM.

In FIG. 55, similarly to FIG. 54, the coordinates of signal point _zs are expressed in the form of complex numbers, with j representing the imaginary unit.

In Figure 55, w#k represents the coordinates of the signal point in the first quadrant of the constellation.

In 2D-NUC, the signal points in the second quadrant of the constellation are placed at positions obtained by moving the signal points in the first quadrant symmetrically with respect to the Q axis, and the signal points in the third quadrant of the constellation are placed at positions obtained by moving the signal points in the first quadrant symmetrically with respect to the origin. And the signal points in the fourth quadrant of the constellation are placed at positions obtained by moving the signal points in the first quadrant symmetrically with respect to the I axis.

Here, when the modulation method is 2 ^m QAM, m bits are treated as one symbol, and the one symbol is mapped to a signal point corresponding to that symbol.

An m-bit symbol can be expressed, for example, by integer values from 0 to 2 ^m -1. If we now let b = 2 ^m /4, then the symbols y(0), y(1), ..., y(2 ^m -1), which are expressed by integer values from 0 to 2 ^m -1, can be classified into four symbols: y(0) to y(b-1), y(b) to y(2b-1), y(2b) to y(3b-1), and y(3b) to y(4b-1).

In FIG. 55, the suffix k of w#k takes an integer value ranging from 0 to b-1, and w#k represents the coordinates of the signal point corresponding to symbol y(k) ranging from symbol y(0) to y(b-1).

The coordinates of the signal point corresponding to symbol y(k+b) in the range of symbols y(b) to y(2b-1) are represented by -conj(w#k), and the coordinates of the signal point corresponding to symbol y(k+2b) in the range of symbols y(2b) to y(3b-1) are represented by conj(w#k). Also, the coordinates of the signal point corresponding to symbol y(k+3b) in the range of symbols y(3b) to y(4b-1) are represented by -w#k.

Here, conj(w#k) represents the complex conjugate of w#k.

For example, when the modulation method is 16QAM, the m = 4-bit symbols y(0), y(1), ..., y(15) are classified into four ^symbols , y(0) through y(3), y(4) through y(7), y(8) through y(11), and y(12) through y(15), with b = 2/4 = 4.

For example, among the symbols y(0) to y(15), the symbol y(12) is a symbol y(k+3b) = y(0+3×4) in the range of symbols y(3b) to y(4b-1), where k = 0, so the coordinates of the signal point corresponding to the symbol y(12) are -w#k = -w0.

Now, if the coding rate r(CR) of the LDPC code is, for example, 9/15, then according to FIG. 55, when the modulation method is 16QAM and the coding rate r is 9/15, w0 is 0.2386+j0.5296, so the coordinate -w0 of the signal point corresponding to the symbol y(12) is -(0.2386+j0.5296).

Figure 56 shows an example of the coordinates of signal points of 1024QAM-1D-NUC used for the coding rates r(CR) = 2/15, 3/15, 4/15, 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12/15, 13/15 of the LDPC code specified in ATSC3.0 when the modulation method is 1024QAM.

In Fig. 56, u#k represents the real part Re( _zs ) and the imaginary part Im( _zs ) of a complex number as the coordinates of the signal point _zs of the 1D-NUC, and is a component of a vector u=(u0, u1,..., u#V-1) called a position vector. The number V of components u#k of the position vector u is given by the formula V=√(2 ^m )/2.

Figure 57 shows the relationship between the 1024QAM symbol y and the position vector u (its components u#k).

Now, let us represent the 10-bit symbol y of 1024QAM as _y0,s , _y1,s , _y2,s , y3 _{,s, y4, s} , _y5,s , _y6,s , _y7,s , _y8,s , _y9,s, from its first bit (most significant bit).

A in FIG. 57 shows the correspondence between the even-numbered five bits _y1,s , y3 _,s , _y5,s , y7 _,s , and y9 _,s of a symbol y and u#k representing the real part Re( _zs ) (in coordinates) of a signal point _zs corresponding to the symbol y.

FIG. 57B shows the correspondence between the odd-numbered five bits _y0,s , y2 _,s , _y4,s , _y6,s , and _y8,s of a symbol y and u#k representing the imaginary part Im( _zs ) of a signal point _zs corresponding to that symbol y.

If the 10-bit symbol y = ( _y0,s , _y1,s , _y2,s , _y3,s , _y4,s , _y5,s , _y6,s , _y7,s , _y8,s , _y9,s ) of 1024QAM is, for example, (0,0,1,0,0,1,1,1,0,0), the odd-numbered five bits ( _y0,s , _y2,s , _y4,s , _y6,s , _y8,s ) are (0,1,0,1,0), and the even-numbered five bits ( _y1,s , _y3 ,s, _y5,s , _y7,s , _y9,s ) are (0,0,1,1,0).

In A of FIG. 57, the even-numbered five bits (0,0,1,1,0) are associated with u11, and therefore the real part Re(z _s ) of the signal point z _s corresponding to the symbol y=(0,0,1,0,0,1,1,1,0,0) is u11.

In FIG. 57B, the odd-numbered five bits (0,1,0,1,0) are associated with u3, and therefore the imaginary part Im(z _s ) of the signal point z _s corresponding to the symbol y=(0,0,1,0,0,1,1,1,0,0) is u3.

On the other hand, if the coding rate r of the LDPC code is, for example, 6/15, then according to FIG. 56 above, for a 1D-NUC used when the modulation method is 1024QAM and the coding rate of the LDPC code r(CR) = 6/15, u3 is 0.1295 and u11 is 0.7196.

Therefore, the real part Re( _zs ) of the signal point _zs corresponding to the symbol y = (0,0,1,0,0,1,1,1,0,0) is u11 = 0.7196, and the imaginary part Im( _zs ) is u3 = 0.1295. As a result, the coordinates of the signal point _zs corresponding to the symbol y = (0,0,1,0,0,1,1,1,0,0) are expressed as 0.7196 + j0.1295.

In addition, the signal points of 1D-NUC are arranged in a grid pattern on a line parallel to the I axis or on a line parallel to the Q axis in the constellation. However, the interval between signal points is not constant. In addition, when transmitting the signal points (the data mapped to them), the average power of the signal points on the constellation can be normalized. If the mean square value of the absolute values of all the signal points (the coordinates of the signal points) on the constellation is expressed as P _ave , normalization can be _{performed by multiplying each signal point zs on the constellation by the reciprocal 1/(√P ave )} , which is the square root of the mean square value P _ave , by the signal point _zs on the constellation.

The transmission system in Figure 7 can use the constellations defined in ATSC3.0 as described above.

Figures 58 to 69 show the coordinates of UC signal points as specified in DVB-C.2.

That is, Fig. 58 is a diagram showing the real part Re( _zq ) of the coordinate _zq of a signal point of QPSK-UC (UC of QPSK) defined in DVB-C.2. Fig. 59 is a diagram showing the imaginary part Im( _zq ) of the coordinate _zq of a signal point of QPSK-UC defined in DVB-C.2.

Fig. 60 is a diagram showing the real part Re( _zq ) of the coordinate _zq of a signal point of 16QAM-UC (UC of 16QAM) defined in DVB-C.2. Fig. 61 is a diagram showing the imaginary part Im( _zq ) of the coordinate _zq of a signal point of 16QAM-UC defined in DVB-C.2.

Fig. 62 is a diagram showing a real part Re( _zq ) of a signal point coordinate _zq of 64QAM-UC (UC of 64QAM) defined in DVB-C.2. Fig. 63 is a diagram showing an imaginary part Im( _zq ) of a signal point coordinate _zq of 64QAM-UC defined in DVB-C.2.

Figure 64 is a diagram showing the real part Re( _zq ) of the coordinate _zq of a signal point of 256QAM-UC (UC of 256QAM) defined in DVB-C.2. Figure 65 is a diagram showing the imaginary part Im( _zq ) of the coordinate _zq of a signal point of 256QAM-UC defined in DVB-C.2.

Fig. 66 is a diagram showing a real part Re( _zq ) of a signal point coordinate _zq of 1024QAM-UC (UC of 1024QAM) defined in DVB-C.2. Fig. 67 is a diagram showing an imaginary part Im( _zq ) of a signal point coordinate _zq of 1024QAM-UC defined in DVB-C.2.

Figure 68 is a diagram showing the real part Re( _zq ) of the coordinate _zq of a signal point of 4096QAM-UC (UC of 4096QAM) specified in DVB-C.2. Figure 69 is a diagram showing the imaginary part Im( _zq ) of the coordinate _zq of a signal point of 4096QAM-UC specified in DVB-C.2.

In Fig.58 to Fig.69, _yi,q represents the (i+1)th bit from the beginning of the m-bit (e.g., 2 bits in QPSK) symbol of ^2mQAM . In addition, when transmitting (data mapped to) a UC signal point, the average power of the signal points on the constellation can be normalized. If the mean square value of the absolute values of all the signal points (coordinates of the signal points) on the constellation is represented as _Pave , normalization can be performed by multiplying each signal point _zq on the constellation by the reciprocal 1/( _√Pave ), which is the square root of the mean square value _Pave , _Pave .

The transmission system in Figure 7 can use the UCs defined in DVB-C.2 as described above.

That is, for the new LDPC codes (corresponding to the check matrix initial value tables) in Figures 30 to 43, 50, and 52, where the code length N is 17280 bits and the coding rates r are 2/16, 3/16, 4/16, 5/16, 6/16, 7/16, 8/16, 9/16, 10/16, 11/16, 12/16, 13/16, and 14/16, the UCs shown in Figures 58 to 69 can be used.

Figures 70 to 78 are diagrams showing examples of the coordinates of NUC signal points that can be used for the new LDPC codes in Figures 30 to 43, Figure 50, and Figure 52, where the code length N is 17280 bits and the coding rates r are 2/16, 3/16, 4/16, 5/16, 6/16, 7/16, 8/16, 9/16, 10/16, 11/16, 12/16, 13/16, and 14/16.

That is, FIG. 70 shows an example of the coordinates of 16QAM-2D-NUC signal points that can be used for the new LDPC code.

Figure 71 shows an example of the coordinates of 64QAM-2D-NUC signal points that can be used for the new LDPC code.

Figures 72 and 73 are diagrams showing examples of the coordinates of 256QAM-2D-NUC signal points that can be used for the new LDPC code.

Note that Figure 73 is a sequel to Figure 72.

70 to 73, similarly to FIG. 55, the coordinates of signal points _zs are expressed in the form of complex numbers, with j representing the imaginary unit.

In Figures 70 to 73, w#k represents the coordinates of the signal point in the first quadrant of the constellation, as in Figure 55.

Here, as explained in Figure 55, if an m-bit symbol is represented by integer values from 0 to ^2m -1 and b = ^2m /4, then the symbols y(0), y(1), ..., y( ^2m -1) represented by integer values from 0 to ^2m -1 can be classified into four symbols: y(0) to y(b-1), y(b) to y(2b-1), y(2b) to y(3b-1), and y(3b) to y(4b-1).

In Figures 70 to 73, as in Figure 55, the suffix k of w#k takes an integer value in the range of 0 to b-1, and w#k represents the coordinates of the signal point corresponding to symbol y(k) in the range of symbols y(0) to y(b-1).

Furthermore, in Figures 70 to 73, as in Figure 55, the coordinates of the signal point corresponding to symbol y(k+3b) in the range of symbols y(3b) to y(4b-1) are represented by -w#k.

However, in Figure 55, the coordinates of the signal point corresponding to symbol y(k+b) in the range of symbols y(b) to y(2b-1) are represented by -conj(w#k), and the coordinates of the signal point corresponding to symbol y(k+2b) in the range of symbols y(2b) to y(3b-1) are represented by conj(w#k), but in Figures 70 to 73, the sign of conj is reversed.

That is, in Figures 70 to 73, the coordinates of the signal point corresponding to symbol y(k+b) in the range of symbols y(b) to y(2b-1) are represented by conj(w#k), and the coordinates of the signal point corresponding to symbol y(k+2b) in the range of symbols y(2b) to y(3b-1) are represented by -conj(w#k).

Figure 74 shows an example of the coordinates of 1024QAM-1D-NUC signal points that can be used for the new LDPC code.

That is, FIG. 74 is a diagram showing the relationship between the real part Re(z _s ) and imaginary part Im(z _s ) of a complex number as the coordinates of a signal point z _s of 1024QAM-1D-NUC, and the position vector u (its component u_k).

Figure 75 shows the relationship between the 1024QAM symbol y and the position vector u (component u#k) in Figure 74.

That is, let us now represent the 10-bit symbol y of 1024QAM, from its first bit (most significant bit), as _y0,s , _y1,s , _y2,s , _y3,s , _{y4,s , y5,s} , _y6,s , _y7,s , _y8,s , _y9,s .

A in FIG. 75 shows the correspondence between the odd-numbered five bits _y0,s , y2 _,s , _y4,s , _y6,s , and _y8,s (from the beginning) of a 10-bit symbol y and a position vector u#k representing the real part Re( _zs ) of (the coordinates of) a signal point zs corresponding to that symbol _y .

FIG. 75B shows the correspondence between the even-numbered five bits _y1,s , y3 _,s , _y5,s , _y7,s , and _y9,s of a 10-bit symbol y and a position vector u#k representing the imaginary part Im( _zs ) of the signal point _zs corresponding to that symbol y.

When a 10-bit symbol y of 1024QAM is mapped to a signal point _zs of 1024QAM-1D-NUC defined in FIGS. 74 and 75, the method of finding the coordinates of the signal point _zs is the same as that described in FIGS. 56 and 57, and therefore the description thereof will be omitted.

Figure 76 shows an example of the coordinates of 4096QAM-1D-NUC signal points that can be used for the new LDPC code.

That is, FIG. 76 is a diagram showing the relationship between the real part Re(z _s ) and imaginary part Im(z _s ) of a complex number as the coordinates of a signal point z _s of 4096QAM-1D-NUC, and the position vector u(u#k).

Figures 77 and 78 show the relationship between the 4096QAM symbol y and the position vector u (component u#k) in Figure 76.

That is, let us represent the 12-bit symbol y of 4096QAM, from its first bit (most significant bit), as _y0,s , _y1,s , _y2,s , _y3,s , _y4,s , y5, _s , _y6,s , _y7,s , _{y8 ,s, y9 ,s, y10,s} , _y11,s .

FIG. 77 shows the correspondence between the odd-numbered 6 bits _y0,s , _y2,s , _y4,s , _y6,s , _y8,s , _y10,s of a 12-bit symbol y and a position vector u#k representing the real part Re( _zs ) of the signal point _zs corresponding to that symbol y.

FIG. 78 shows the correspondence between the even-numbered 6 bits _y1,s , y3 _,s , _y5,s , _y7,s , _y9,s , and _y11,s of a 12-bit symbol y and a position vector u#k representing the imaginary part Im( _zs ) of the signal point _zs corresponding to that symbol y.

When a 12-bit symbol y of 4096QAM is mapped to a signal point _zs of 4096QAM-1D-NUC defined in Figs. 76 to 78, the method of finding the coordinates of the signal point _zs is the same as that described in Figs. 56 and 57, and therefore the description thereof will be omitted.

When transmitting (data mapped to) the NUC constellation points in Figures 70 to 78, the average power of the constellation points on the constellation can be normalized. If the mean square value of the absolute values of all (the coordinates of) the constellation points on the constellation is represented as P _ave , normalization can be performed by multiplying each constellation point _zs on the constellation by the reciprocal 1/(√P _ave ), which is the square root of the mean square value _{P ave} . In addition, in the above-mentioned FIG. 57, the odd-numbered bits of the symbol y are associated with the position vector u#k representing the imaginary part Im( _zs ) of the signal point _zs , and the even-numbered bits of the symbol y are associated with the position vector u#k representing the real part Re( _zs ) of the signal point _zs . However, in FIG. 75, FIG. 77 and FIG. 78, on the other hand, the odd-numbered bits of the symbol y are associated with the position vector u#k representing the real part Re( _zs ) of the signal point _zs , and the even-numbered bits of the symbol y are associated with the position vector u#k representing the imaginary part Im( _zs ) of the signal point _zs .

<Block interleaver 25>

Figure 79 is a diagram explaining the block interleaving performed by the block interleaver 25 in Figure 9.

Block interleaving is performed by dividing one codeword of an LDPC code into a part called part 1 and a part called part 2, starting from the beginning.

If the length of part 1 (number of bits) is represented as Npart1 and the length of part 2 is represented as Npart2, then Npart1 + Npart2 is equal to the code length N.

Conceptually, in block interleaving, columns serving as storage areas for storing Npart1/m bits are arranged in one direction, the column (vertical) direction, and a number m, equal to the number of bits in the symbol, are arranged in the row direction perpendicular to the column direction, and each column is divided from the top into small units of 360 bits, which is the parallel factor P. These small column units are also called column units.

In block interleaving, as shown in Figure 79, part 1 of an LDPC code for one codeword is written from top to bottom (column direction) in the first column unit of a column, moving from left to right columns.

Then, when writing to the first column unit in the rightmost column is completed, as shown in FIG. 79, the process returns to the leftmost column, and writing is performed from top to bottom in the second column unit of the column, proceeding from left to right, and so on until part 1 of the LDPC code for one codeword is written.

When writing of part 1 of the LDPC code for one code word is completed, part 1 of the LDPC code is read out in m-bit units in the row direction from the first row of all m columns, as shown in Figure 79.

The m-bit units of part 1 are supplied as m-bit symbols from the block interleaver 25 to the mapper 117 (Figure 8).

The reading of part 1 in m-bit units is performed sequentially from the bottom row of m columns, and when the reading of part 1 is completed, part 2 is divided into m-bit units from the beginning and supplied from the block interleaver 25 to the mapper 117 as an m-bit symbol.

Therefore, part 1 is symbolized while being interleaved, and part 2 is symbolized sequentially, divided into m bits, without being interleaved.

The length of the column, Npart1/m, is a multiple of the parallel factor P, 360, and so that Npart1/m is a multiple of 360, an LDPC code for one codeword is divided into part 1 and part 2.

Figure 80 shows examples of part 1 and part 2 of an LDPC code with a code length N of 17280 bits when the modulation methods are QPSK, 16QAM, 64QAM, and 256QAM.

When the modulation method is QPSK, 16QAM, 64QAM, or 256QAM, in all cases, part 1 is 17280 bits and part 2 is 0 bits.

<Group-wise interleaving>

Figure 81 is a diagram explaining the group-wise interleaving performed by the group-wise interleaver 24 in Figure 9.

As shown in FIG. 81, in group-wise interleaving, the LDPC code of one codeword is divided into 360-bit units, which is equal to the parallel factor P, from the beginning of the codeword. The 360 bits of each unit are treated as a bit group, and the LDPC code of one codeword is interleaved in bit group units according to a predetermined pattern (hereinafter also referred to as a GW pattern).

Here, when an LDPC code of one codeword is divided into bit groups, the (i+1)th bit group from the beginning is hereinafter also referred to as bit group i.

When the parallel factor P is 360, for example, an LDPC code with a code length N of 1800 bits is divided into 5 (=1800/360) bit groups, namely, bit groups 0, 1, 2, 3, and 4. Furthermore, for example, an LDPC code with a code length N of 69120 bits is divided into 192 (=69120/360) bit groups, namely, bit groups 0, 1, ..., 191. Furthermore, for example, an LDPC code with a code length N of 17280 bits is divided into 48 (=17280/360) bit groups, namely, bit groups 0, 1, ..., 47.

In the following, GW patterns are represented by a sequence of numbers that represent bit groups. For example, for an LDPC code with a code length N of 1800 bits and five bit groups 0,1,2,3,4, a GW pattern of 4,2,0,3,1 indicates that the sequence of bit groups 0,1,2,3,4 is interleaved (rearranged) into the sequence of bit groups 4,2,0,3,1. Note that bit group sequences and GW patterns are represented by a comma-separated sequence of numbers that represent bit groups (e.g., 4,2,0,3,1), as well as a space-separated sequence of numbers that represent bit groups (e.g., 4 2 0 3 1).

For example, let x _i represent the (i+1)th code bit from the beginning of an LDPC code whose code length N is 1800 bits.

In this case, according to the group-wise interleaving of GW patterns 4, 2, 0, 3, 1, the 1800-bit LDPC code {x ₀ , x ₁ , ..., x ₁₇₉₉ } is interleaved in the order {x ₁₄₄₀ , x ₁₄₄₁ , ..., x ₁₇₉₉ }, {x ₇₂₀ , x ₇₂₁ , ..., x ₁₀₇₉ }, {x ₀ , x ₁ , ..., x ₃₅₉ }, {x ₁₀₈₀ , x ₁₀₈₁ , ..., x ₁₄₃₉ }, {x ₃₆₀ , x ₃₆₁ , ..., x ₇₁₉ }.

GW patterns can be set for each code length N of the LDPC code, each coding rate r, each modulation method, each constellation, and even for combinations of two or more of code length N, coding rate r, modulation method, and constellation.

<Example of GW pattern for LDPC code>

Figure 82 shows a first example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 82, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47
are interleaved in the sequence.

Figure 83 shows a second example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 83, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
19 33 45 22 43 23 46 32 11 40 13 34 14 47 0 12 6 26 37 4 5 17 25 30 39 29 27 28 10 21 36 9 3 20 24 42 7 41 44 38 15 8 31 16 2 1 35 18
are interleaved in the sequence.

Figure 84 shows a third example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 84, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47
are interleaved in the sequence.

Figure 85 shows a fourth example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 85, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47
are interleaved in the sequence.

Figure 86 shows a fifth example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 86, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47
are interleaved in the sequence.

Figure 87 shows a sixth example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 87, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47
are interleaved in the sequence.

Figure 88 shows a seventh example of a GW pattern for an LDPC code with a code length N of 17,280 bits.

According to the GW pattern in FIG. 88, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
0 34 30 6 11 35 5 24 4 13 15 16 3 31 39 40 37 47 28 12 36 42 33 22 20 8 9 44 29 18 25 21 23 10 14 26 45 7 27 46 1 2 17 41 19 43 38 32
are interleaved in the sequence.

Figure 89 shows an eighth example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern in FIG. 89, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
33 16 0 26 35 31 21 34 42 43 32 29 7 47 37 28 5 9 30 25 3 17 23 24 41 45 20 12 27 39 8 4 1 6 2 38 10 40 18 19 46 11 36 13 22 14 15 44
are interleaved in the sequence.

Figure 90 shows a ninth example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 90, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
41 10 21 37 9 8 11 27 16 23 25 2 34 7 29 28 5 15 31 45 4 43 33 22 18 13 35 30 6 12 44 1 20 40 42 39 19 17 36 38 26 0 32 3 47 14 24 46
are interleaved in the sequence.

Figure 91 shows a tenth example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern in FIG. 91, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
15 21 29 10 12 32 1 9 31 47 23 30 26 18 0 28 7 20 43 44 3 45 5 17 16 46 40 39 6 38 34 36 22 33 27 24 25 13 14 37 19 8 42 11 4 2 35 41
are interleaved in the sequence.

Figure 92 shows an eleventh example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 92, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47
are interleaved in the sequence.

Figure 93 shows a 12th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 93, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
31 23 1 42 36 25 47 3 12 30 32 8 11 27 21 40 16 13 34 4 26 35 46 20 29 28 5 43 18 39 24 14 0 10 7 41 37 9 38 33 2 6 19 45 17 15 22 44
are interleaved in the sequence.

Figure 94 shows a thirteenth example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 94, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
46 11 23 33 10 0 17 47 20 5 38 29 28 16 41 27 2 31 43 37 34 12 35 24 21 44 40 36 32 39 4 19 26 6 30 9 42 1 22 8 3 45 14 15 13 7 25 18
are interleaved in the sequence.

Figure 95 shows a 14th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern in FIG. 95, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
16 32 33 43 3 29 0 22 40 24 44 8 20 13 15 45 7 34 39 42 25 28 18 26 38 10 11 41 47 23 6 1 14 4 12 31 21 19 37 36 30 5 46 27 35 2 9 17
are interleaved in the sequence.

Figure 96 shows a 15th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 96, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
23 42 33 17 37 2 22 14 21 0 12 44 30 1 25 35 46 13 10 24 20 15 45 31 41 43 28 36 16 4 32 18 3 6 34 11 40 5 38 27 29 8 26 7 39 9 47 19
are interleaved in the sequence.

Figure 97 shows a 16th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern in FIG. 97, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
7 0 8 39 17 3 32 2 13 19 16 14 5 10 27 35 45 26 44 43 11 24 28 34 20 29 22 41 18 9 37 12 21 4 46 33 15 36 42 1 40 25 23 30 6 38 31 47
are interleaved in the sequence.

Figure 98 shows a 17th example of a GW pattern for an LDPC code with a code length N of 17,280 bits.

According to the GW pattern of FIG. 98, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
1 28 12 35 23 36 24 17 10 14 15 37 18 13 41 38 33 29 16 21 27 4 9 31 45 40 0 46 7 43 30 34 8 44 47 2 20 6 42 3 22 39 5 32 11 19 25 26
are interleaved in the sequence.

Figure 99 shows an 18th example of a GW pattern for an LDPC code with a code length N of 17,280 bits.

According to the GW pattern in FIG. 99, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
9 8 3 40 27 4 7 45 28 29 14 41 20 6 21 5 36 12 31 39 30 15 37 10 34 25 1 47 26 13 32 43 44 24 33 16 42 2 22 19 18 35 23 46 11 17 38 0
are interleaved in the sequence.

Figure 100 shows a 19th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 100, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
12 42 40 41 20 18 27 24 39 6 0 15 8 31 10 3 13 46 4 37 33 25 44 2 16 23 28 14 17 43 45 1 35 38 26 21 36 22 47 11 34 29 30 32 19 7 5 9
are interleaved in the sequence.

Figure 101 shows a 20th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern in FIG. 101, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
33 18 21 29 14 4 35 32 26 15 11 6 1 47 38 17 45 27 2 5 16 12 23 25 3 0 42 13 41 46 9 24 40 43 7 31 39 34 30 20 8 36 22 10 19 28 37 44
are interleaved in the sequence.

Figure 102 shows a 21st example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 102, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
7 28 41 8 6 12 14 47 4 38 32 37 23 33 15 46 22 0 34 24 40 45 27 19 43 11 36 9 17 21 31 44 2 1 26 13 42 30 35 5 29 25 16 20 39 10 18 3
are interleaved in the sequence.

Figure 103 shows a 22nd example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 103, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
30 14 40 26 21 5 12 3 18 17 11 38 4 46 7 31 0 1 27 36 8 10 2 22 13 9 37 42 41 32 15 39 23 25 34 24 35 28 20 16 19 33 6 43 29 45 47 44
are interleaved in the sequence.

Figure 104 shows a 23rd example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 104, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
23 20 14 9 44 41 19 36 38 13 16 28 0 8 2 39 31 29 21 10 11 33 32 27 46 7 5 35 26 1 43 40 37 17 47 30 6 18 15 42 3 25 4 22 24 12 45 34
are interleaved in the sequence.

Figure 105 shows a 24th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 105, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
37 30 14 13 2 31 27 9 46 41 47 18 23 28 43 10 39 42 16 22 36 8 33 32 4 1 45 19 12 6 35 0 24 25 15 38 44 7 26 21 34 40 29 20 11 5 17 3
are interleaved in the sequence.

Figure 106 shows a 25th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 106, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
6 28 25 38 43 11 21 31 47 8 17 39 23 27 30 32 3 35 12 7 1 16 18 36 10 24 41 4 44 22 5 33 46 29 0 26 9 42 37 45 15 40 2 19 14 20 34 13
are interleaved in the sequence.

Figure 107 shows a 26th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 107, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
39 11 12 7 3 1 40 31 27 0 45 42 6 5 24 36 46 19 34 22 29 13 35 2 17 33 20 14 15 25 38 9 41 30 44 18 8 28 37 4 32 47 16 43 21 23 26 10
are interleaved in the sequence.

Figure 108 shows a 27th example of a GW pattern for an LDPC code with a code length N of 17,280 bits.

According to the GW pattern of FIG. 108, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
7 19 31 20 36 35 2 4 46 12 28 21 39 43 26 23 32 5 37 3 11 34 18 45 24 1 13 47 10 27 0 9 33 25 8 40 6 16 22 29 42 38 14 44 41 17 30 15
are interleaved in the sequence.

Figure 109 shows a 28th example of a GW pattern for an LDPC code with a code length N of 17,280 bits.

According to the GW pattern of FIG. 109, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
12 7 39 31 30 44 14 33 35 17 37 27 2 28 9 26 32 3 46 0 34 6 43 25 21 47 18 45 5 20 13 38 11 29 16 36 8 40 15 41 10 23 1 19 4 22 42 24
are interleaved in the sequence.

Figure 110 shows a 29th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 110, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
20 19 13 25 32 9 5 24 39 4 29 40 14 18 43 46 21 44 10 15 35 3 23 47 37 12 30 33 27 36 8 28 38 7 42 22 2 0 6 16 45 26 17 11 31 34 41 1
are interleaved in the sequence.

Figure 111 shows the 30th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern in FIG. 111, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
19 20 44 3 6 28 13 15 16 24 9 34 39 8 17 40 29 31 22 10 11 7 35 42 23 2 14 37 33 1 26 45 38 12 47 30 5 18 46 0 41 27 4 21 43 25 36 32
are interleaved in the sequence.

Figure 112 shows a 31st example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 112, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
4 26 7 21 43 42 33 17 35 19 10 39 27 13 18 34 38 3 28 36 1 5 44 37 16 30 14 9 32 47 29 2 31 23 0 24 11 8 6 46 40 45 15 22 25 20 12 41
are interleaved in the sequence.

Figure 113 shows a 32nd example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 113, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
8 28 33 21 1 39 34 7 0 17 5 41 23 2 14 10 29 25 13 18 35 38 27 44 20 32 31 11 40 30 24 3 36 22 15 37 16 6 42 45 19 47 12 26 43 9 46 4
are interleaved in the sequence.

Figure 114 shows a 33rd example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 114, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
0 39 23 44 19 21 35 13 36 27 47 3 31 11 9 41 43 8 14 26 6 5 15 16 38 7 32 22 30 33 37 40 28 45 12 24 17 42 20 29 1 4 10 2 25 18 46 34
are interleaved in the sequence.

Figure 115 shows a 34th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 115, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
11 0 42 24 46 27 25 3 1 41 22 40 19 18 14 36 33 4 47 12 39 30 13 5 2 7 31 9 38 35 15 43 45 44 28 20 32 21 26 23 6 10 8 37 17 34 29 16
are interleaved in the sequence.

Figure 116 shows the 35th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 116, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
5 45 42 35 13 41 2 29 15 11 16 0 8 1 33 34 44 7 43 22 24 19 9 38 18 12 26 20 28 21 10 30 40 6 46 37 47 17 3 32 4 39 23 25 36 14 31 27
are interleaved in the sequence.

Figure 117 shows the 36th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern in FIG. 117, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
18 16 21 2 43 10 44 42 19 15 20 26 1 38 46 28 17 29 6 22 7 32 31 30 24 3 8 9 12 37 47 40 39 5 35 11 25 45 34 33 23 4 14 27 13 41 36 0
are interleaved in the sequence.

Figure 118 shows the 37th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 118, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
28 9 4 27 17 10 12 6 19 30 1 23 39 14 38 34 46 8 15 43 13 47 0 44 7 24 45 18 25 29 37 42 22 31 11 36 20 32 41 33 2 26 21 5 3 16 40 35
are interleaved in the sequence.

Figure 119 shows the 38th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern in FIG. 119, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
5 37 36 38 16 21 41 44 10 18 26 27 15 1 43 2 33 14 9 30 8 12 23 4 13 35 31 3 34 19 42 47 46 29 0 25 20 17 39 45 28 6 22 11 32 40 24 7
are interleaved in the sequence.

Figure 120 shows the 39th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 120, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
11 1 12 21 13 15 24 36 34 0 37 9 14 39 19 16 17 28 40 29 23 46 30 38 33 3 6 18 26 7 27 45 10 25 4 42 31 43 35 32 5 8 44 41 47 22 20 2
are interleaved in the sequence.

Figure 121 shows the 40th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 121, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
3 41 6 42 21 2 25 45 8 39 34 26 47 43 23 20 13 16 38 24 5 40 0 11 7 31 32 15 36 33 9 12 10 30 29 14 18 35 46 4 28 19 1 44 37 27 17 22
are interleaved in the sequence.

Figure 122 shows a 41st example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 122, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
40 42 11 10 15 6 34 37 16 45 25 47 32 8 17 26 29 7 18 21 46 44 28 27 20 38 43 36 33 5 24 9 13 2 0 4 39 31 1 22 30 12 14 41 23 3 19 35
are interleaved in the sequence.

Figure 123 shows a 42nd example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 123, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
6 0 20 18 37 27 39 3 1 2 46 11 24 36 14 15 4 16 10 13 35 23 26 30 19 42 7 9 33 40 12 34 22 5 28 21 32 38 44 25 17 41 29 45 8 47 31 43
are interleaved in the sequence.

Figure 124 shows a 43rd example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 124, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
8 25 12 9 26 37 35 28 14 5 6 2 29 38 22 31 11 21 17 33 42 43 36 45 20 27 44 13 16 46 10 30 3 32 19 1 15 4 18 40 47 7 34 24 41 23 39 0
are interleaved in the sequence.

Figure 125 shows a 44th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 125, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
7 17 26 27 9 39 46 47 32 12 35 25 14 11 22 23 16 29 38 33 34 4 40 10 5 18 37 1 24 44 30 3 0 45 28 13 15 20 6 21 31 19 2 8 41 36 42 43
are interleaved in the sequence.

Figure 126 shows a 45th example of a GW pattern for an LDPC code with a code length N of 17280 bits.

According to the GW pattern of FIG. 126, the arrangement of bit groups 0 to 47 of the 17280-bit LDPC code is
11 14 32 27 44 43 0 47 1 8 35 33 7 2 41 15 13 4 23 30 16 42 46 24 9 17 21 20 18 5 19 12 3 34 28 40 39 37 31 38 45 36 6 22 26 10 25 29
are interleaved in the sequence.

The above first to forty-fifth examples of GW patterns for an LDPC code with a code length N of 17280 bits can be applied to any combination of an LDPC code with a code length N of 17280 bits, any coding rate r, any modulation method, and any constellation.

However, for group-wise interleaving, the error rate can be further improved for each combination by setting the GW pattern to be applied for each combination of the LDPC code length N, the LDPC code coding rate r, the modulation method, and the constellation.

The GW pattern in FIG. 82 can achieve a particularly good error rate by applying it to, for example, the type A code with r=3/16 (corresponding to the check matrix initial value table) in FIG. 31, QPSK, and the combination of QPSK-UC in FIG. 58 and FIG. 59.

The GW pattern in Figure 83 can achieve a particularly good error rate by applying it to, for example, the Type A code with r=5/16 in Figure 33, QPSK, and the combination of QPSK-UC in Figures 58 and 59.

The GW pattern in Figure 84 can achieve particularly good error rates when applied to, for example, the Type B code with r=7/16 in Figure 36, QPSK, and the combination of QPSK-UC in Figures 58 and 59.

The GW pattern in Figure 85 can achieve a particularly good error rate by applying it to, for example, the new type B code with r=9/16 in Figure 52, QPSK, and the combination of QPSK-UC in Figures 58 and 59.

The GW pattern in Figure 86 can achieve a particularly good error rate when applied to, for example, the Type B code with r=11/16 in Figure 40, QPSK, and the combination of QPSK-UC in Figures 58 and 59.

The GW pattern in Figure 87 can achieve a particularly good error rate when applied to, for example, the Type B code with r=13/16 in Figure 42, QPSK, and the combination of QPSK-UC in Figures 58 and 59.

The GW pattern in Figure 88 can achieve a particularly good error rate when applied to, for example, a combination of the Type A code with r=3/16 in Figure 31, 16QAM, and 16QAM-UC in Figures 60 and 61.

The GW pattern in Figure 89 can achieve a particularly good error rate when applied to, for example, a combination of the Type A code with r=5/16 in Figure 33, 16QAM, and 16QAM-UC in Figures 60 and 61.

The GW pattern in Figure 90 can achieve a particularly good error rate when applied to, for example, a combination of the Type B code with r=7/16 in Figure 36, 16QAM, and 16QAM-UC in Figures 60 and 61.

The GW pattern in Figure 91 can achieve a particularly good error rate when applied to, for example, the combination of the new type B code with r=9/16 in Figure 52, 16QAM, and 16QAM-UC in Figures 60 and 61.

The GW pattern in Figure 92 can achieve a particularly good error rate when applied to, for example, a combination of the Type B code with r=11/16 in Figure 40, 16QAM, and 16QAM-UC in Figures 60 and 61.

The GW pattern in Figure 93 can achieve a particularly good error rate when applied to, for example, a combination of the Type B code with r=13/16 in Figure 42, 16QAM, and 16QAM-UC in Figures 60 and 61.

The GW pattern in Figure 94 can achieve a particularly good error rate by applying it to, for example, a combination of the Type A code with r=2/16 in Figure 30, 16QAM, and 16QAM-2D-NUC in Figure 70.

The GW pattern in Figure 95 can achieve a particularly good error rate by applying it to, for example, the combination of the new type A code with r=4/16 in Figure 50, 16QAM, and 16QAM-2D-NUC in Figure 70.

The GW pattern in FIG. 96 can achieve a particularly good error rate when applied to, for example, a combination of the Type A code with r=6/16 in FIG. 34, 16QAM, and 16QAM-2D-NUC in FIG. 70.

The GW pattern in Figure 97 can achieve a particularly good error rate by applying it to, for example, a combination of the Type B code with r=8/16 in Figure 37, 16QAM, and 16QAM-2D-NUC in Figure 70.

The GW pattern in Figure 98 can achieve a particularly good error rate by applying it to, for example, a combination of Type B code with r=10/16 in Figure 39, 16QAM, and 16QAM-2D-NUC in Figure 70.

The GW pattern in Figure 99 can achieve a particularly good error rate by applying it to, for example, a combination of Type B code with r=12/16 in Figure 41, 16QAM, and 16QAM-2D-NUC in Figure 70.

The GW pattern in Figure 100 can achieve a particularly good error rate by applying it to, for example, a combination of Type B code with r=14/16 in Figure 43, 16QAM, and 16QAM-2D-NUC in Figure 70.

The GW pattern in Figure 101 can achieve a particularly good error rate when applied to, for example, the combination of Type A code with r=2/16 in Figure 30, 64QAM, and 64QAM-UC in Figures 62 and 63.

The GW pattern in Figure 102 can achieve a particularly good error rate by applying it to, for example, the combination of the new type A code with r=4/16 in Figure 50, 64QAM, and 64QAM-UC in Figures 62 and 63.

The GW pattern in Figure 103 can achieve a particularly good error rate when applied to, for example, the combination of Type A code with r=6/16 in Figure 34, 64QAM, and 64QAM-UC in Figures 62 and 63.

The GW pattern in Figure 104 can achieve a particularly good error rate when applied to, for example, a combination of the Type B code with r=8/16 in Figure 37, 64QAM, and 64QAM-UC in Figures 62 and 63.

The GW pattern in Figure 105 can achieve a particularly good error rate when applied to, for example, a combination of the Type B code with r=10/16 in Figure 39, 64QAM, and 64QAM-UC in Figures 62 and 63.

The GW pattern in Figure 106 can achieve a particularly good error rate when applied to, for example, a combination of the Type B code with r=12/16 in Figure 41, 64QAM, and 64QAM-UC in Figures 62 and 63.

The GW pattern in Figure 107 can achieve a particularly good error rate when applied to, for example, a combination of the Type B code with r=14/16 in Figure 43, 64QAM, and 64QAM-UC in Figures 62 and 63.

The GW pattern in FIG. 108 can achieve a particularly good error rate by applying it to, for example, a combination of the Type A code with r=3/16 in FIG. 31, 64QAM, and 64QAM-2D-NUC in FIG. 71.

The GW pattern in FIG. 109 can achieve a particularly good error rate by applying it to, for example, a combination of the Type A code with r=5/16 in FIG. 33, 64QAM, and 64QAM-2D-NUC in FIG. 71.

The GW pattern in FIG. 110 can achieve a particularly good error rate by applying it to, for example, a combination of the Type B code with r=7/16 in FIG. 36, 64QAM, and 64QAM-2D-NUC in FIG. 71.

The GW pattern in Figure 111 can achieve a particularly good error rate by applying it to, for example, the combination of the new type B code with r=9/16 in Figure 52, 64QAM, and 64QAM-2D-NUC in Figure 71.

The GW pattern in FIG. 112 can achieve a particularly good error rate by applying it to, for example, a combination of the Type B code with r=11/16 in FIG. 40, 64QAM, and 64QAM-2D-NUC in FIG. 71.

The GW pattern in FIG. 113 can achieve a particularly good error rate when applied to, for example, a combination of the Type B code with r=13/16 in FIG. 42, 64QAM, and 64QAM-2D-NUC in FIG. 71.

The GW pattern in Figure 114 can achieve a particularly good error rate when applied to, for example, the combination of Type A code with r=3/16 in Figure 31, 256QAM, and 256QAM-UC in Figures 64 and 65.

The GW pattern in Figure 115 can achieve particularly good error rates when applied to, for example, the combination of Type A code with r=5/16 in Figure 33, 256QAM, and 256QAM-UC in Figures 64 and 65.

The GW pattern in Figure 116 can achieve particularly good error rates when applied to, for example, a combination of the Type B code with r=7/16 in Figure 36, 256QAM, and 256QAM-UC in Figures 64 and 65.

The GW pattern in Figure 117 can achieve a particularly good error rate when applied to, for example, the combination of the new type B code with r=9/16 in Figure 52, 256QAM, and 256QAM-UC in Figures 64 and 65.

The GW pattern in Figure 118 can achieve particularly good error rates when applied to, for example, the combination of Type B code with r=11/16 in Figure 40, 256QAM, and 256QAM-UC in Figures 64 and 65.

The GW pattern in Figure 119 can achieve particularly good error rates when applied to, for example, a combination of Type B code with r=13/16 in Figure 42, 256QAM, and 256QAM-UC in Figures 64 and 65.

The GW pattern in Figure 120 can achieve particularly good error rates when applied to, for example, a combination of the Type A code with r=2/16 in Figure 30, 256QAM, and 256QAM-2D-NUC in Figures 72 and 73.

The GW pattern in Figure 121 can achieve a particularly good error rate by applying it to, for example, the combination of the new type A code with r=4/16 in Figure 50, 256QAM, and 256QAM-2D-NUC in Figures 72 and 73.

The GW pattern in FIG. 122 can achieve a particularly good error rate when applied to, for example, a combination of the Type A code with r=6/16 in FIG. 34, 256QAM, and 256QAM-2D-NUC in FIG. 72 and FIG. 73.

The GW pattern in Figure 123 can achieve particularly good error rates when applied to, for example, a combination of the Type B code with r=8/16 in Figure 37, 256QAM, and 256QAM-2D-NUC in Figures 72 and 73.

The GW pattern in Figure 124 can achieve particularly good error rates when applied to, for example, a combination of Type B code with r=10/16 in Figure 39, 256QAM, and 256QAM-2D-NUC in Figures 72 and 73.

The GW pattern in Figure 125 can achieve particularly good error rates when applied to, for example, a combination of the Type B code with r=12/16 in Figure 41, 256QAM, and 256QAM-2D-NUC in Figures 72 and 73.

The GW pattern in Figure 126 can achieve particularly good error rates when applied to, for example, a combination of Type B code with r=14/16 in Figure 43, 256QAM, and 256QAM-2D-NUC in Figures 72 and 73.

<Example of the configuration of the receiving device 12>

Figure 127 is a block diagram showing an example configuration of the receiving device 12 in Figure 7.

The OFDM operation unit 151 receives an OFDM signal from the transmitting device 11 (FIG. 7) and performs signal processing on the OFDM signal. The data obtained by the signal processing performed by the OFDM operation unit 151 is supplied to the frame management unit 152.

The frame management unit 152 processes (interprets) the frames composed of data supplied from the OFDM processing unit 151, and supplies the resulting target data signal and control data signal to frequency deinterleavers 161 and 153, respectively.

The frequency deinterleaver 153 performs frequency deinterleaving on the data from the frame management unit 152 on a symbol-by-symbol basis and supplies the data to the demapper 154.

The demapper 154 performs orthogonal demodulation by demapping (signal point arrangement decoding) the data (constellation data) from the frequency deinterleaver 153 based on the signal point arrangement (constellation) determined by the orthogonal modulation performed on the transmitting device 11 side, and supplies the resulting data (LDPC code (likelihood)) to the LDPC decoder 155.

The LDPC decoder 155 (decoding unit) performs LDPC decoding of the LDPC code from the demapper 154, and supplies the resulting LDPC target data (here, the BCH code) to the BCH decoder 156.

The BCH decoder 156 performs BCH decoding on the LDPC target data from the LDPC decoder 155, and outputs the resulting control data (signaling).

On the other hand, the frequency deinterleaver 161 performs frequency deinterleaving on the data from the frame management unit 152 on a symbol-by-symbol basis and supplies the data to a SISO/MISO decoder 162.

The SISO/MISO decoder 162 performs space-time decoding of the data from the frequency deinterleaver 161 and supplies it to the time deinterleaver 163.

The time deinterleaver 163 performs time deinterleaving on the data from the SISO/MISO decoder 162 on a symbol-by-symbol basis and supplies the data to the demapper 164.

The demapper 164 performs orthogonal demodulation by demapping (signal point arrangement decoding) the data (constellation data) from the time deinterleaver 163 based on the signal point arrangement (constellation) determined by the orthogonal modulation performed on the transmitting device 11 side, and supplies the resulting data to the bit deinterleaver 165.

The bit deinterleaver 165 performs bit deinterleaving of the data from the demapper 164, and supplies the LDPC code (likelihood), which is the bit deinterleaved data, to the LDPC decoder 166.

The LDPC decoder 166 performs LDPC decoding on the LDPC code from the bit deinterleaver 165, and supplies the resulting LDPC target data (here, the BCH code) to the BCH decoder 167.

The BCH decoder 167 performs BCH decoding on the LDPC target data from the LDPC decoder 155, and supplies the resulting data to the BB DeScrambler 168.

The BB descrambler 168 performs BB descrambling on the data from the BCH decoder 167 and supplies the resulting data to the null deletion unit (Null Deletion) 169.

The null deletion unit 169 deletes the nulls inserted by the padder 112 in FIG. 8 from the data from the BB descrambler 168 and supplies the data to the demultiplexer 170.

The demultiplexer 170 separates one or more streams (target data) multiplexed into the data from the null deletion unit 169, performs the necessary processing, and outputs them as an output stream.

The receiving device 12 can be configured without some of the blocks shown in FIG. 127. That is, for example, when the transmitting device 11 (FIG. 8) is configured without the time interleaver 118, the SISO/MISO encoder 119, the frequency interleaver 120, and the frequency interleaver 124, the receiving device 12 can be configured without the time deinterleaver 163, the SISO/MISO decoder 162, the frequency deinterleaver 161, and the frequency deinterleaver 153, which are blocks corresponding to the time interleaver 118, the SISO/MISO encoder 119, the frequency interleaver 120, and the frequency interleaver 124 of the transmitting device 11, respectively.

<Example of the configuration of bit deinterleaver 165>

Figure 128 is a block diagram showing an example configuration of the bit deinterleaver 165 in Figure 127.

The bit deinterleaver 165 is composed of a block deinterleaver 54 and a group-wise deinterleaver 55, and performs (bit) deinterleaving of the symbol bits of the symbols, which are the data from the demapper 164 (Figure 127).

That is, the block deinterleaver 54 performs block deinterleaving (the reverse process of block interleaving) corresponding to the block interleaving performed by the block interleaver 25 in FIG. 9 on the symbol bits of the symbol from the demapper 164, that is, block deinterleaving that returns the positions of the code bits (of the likelihoods) of the LDPC code rearranged by the block interleaving to their original positions, and supplies the resulting LDPC code to the group-wise deinterleaver 55.

The group-wise deinterleaver 55 performs group-wise deinterleaving (the inverse process of group-wise interleaving) on the LDPC code from the block deinterleaver 54, which corresponds to the group-wise interleaving performed by the group-wise interleaver 24 in FIG. 9. In other words, the group-wise deinterleaver 55 performs group-wise deinterleaving to return the code bits of the LDPC code, whose order has been changed on a bit-group basis by the group-wise interleaving described in FIG. 81, to their original order by rearranging them on a bit-group basis.

Here, when parity interleaving, group-wise interleaving, and block interleaving have been performed on the LDPC code supplied from the demapper 164 to the bit deinterleaver 165, the bit deinterleaver 165 can perform all of the following: parity deinterleaving corresponding to parity interleaving (the inverse process of parity interleaving, i.e., parity deinterleaving that returns the code bits of the LDPC code whose order has been changed by parity interleaving to their original order), block deinterleaving corresponding to block interleaving, and group-wise deinterleaving corresponding to group-wise interleaving.

However, in the bit deinterleaver 165 of FIG. 128, a block deinterleaver 54 that performs block deinterleaving corresponding to block interleaving and a group-wise deinterleaver 55 that performs group-wise deinterleaving corresponding to group-wise interleaving are provided, but a block that performs parity deinterleaving corresponding to parity interleaving is not provided, and parity deinterleaving is not performed.

Therefore, the bit deinterleaver 165 (group-wise deinterleaver 55) supplies the LDPC decoder 166 with an LDPC code that has been block deinterleaved and group-wise deinterleaved, but has not been parity deinterleaved.

The LDPC decoder 166 performs LDPC decoding of the LDPC code from the bit deinterleaver 165 based on a transformed check matrix obtained by performing at least column permutation equivalent to parity interleaving on the type B check matrix H used for LDPC encoding by the LDPC encoder 115 in FIG. 8, or a transformed check matrix (FIG. 29) obtained by performing row permutation on the type A check matrix (FIG. 27), and outputs the resulting data as the decoded result of the LDPC target data.

Figure 129 is a flowchart explaining the processing performed by the demapper 164, bit deinterleaver 165, and LDPC decoder 166 in Figure 128.

In step S111, the demapper 164 demaps and orthogonally demodulates the data from the time deinterleaver 163 (data on the constellation mapped to the signal points) and supplies it to the bit deinterleaver 165, and the process proceeds to step S112.

In step S112, the bit deinterleaver 165 deinterleaves (bit deinterleaves) the data from the demapper 164, and processing proceeds to step S113.

That is, in step S112, in the bit deinterleaver 165, the block deinterleaver 54 performs block deinterleaving on the data (symbols) from the demapper 164, and supplies the resulting code bits of the LDPC code to the group-wise deinterleaver 55.

The group-wise deinterleaver 55 performs group-wise deinterleaving on the LDPC code from the block deinterleaver 54, and supplies the resulting LDPC code (the likelihood of the LDPC code) to the LDPC decoder 166.

In step S113, the LDPC decoder 166 performs LDPC decoding of the LDPC code from the group-wise deinterleaver 55 based on the check matrix H used for LDPC encoding by the LDPC encoder 115 in FIG. 8, that is, based on a converted check matrix obtained from the check matrix H, for example, and outputs the resulting data to the BCH decoder 167 as the decoded result of the LDPC target data.

In FIG. 128, as in the case of FIG. 9, for ease of explanation, the block deinterleaver 54 that performs block deinterleaving and the group-wise deinterleaver 55 that performs group-wise deinterleaving are configured separately, but the block deinterleaver 54 and the group-wise deinterleaver 55 can be configured as an integrated unit.

In addition, if group-wise interleaving is not performed in the transmitting device 11, the receiving device 12 can be configured without providing a group-wise deinterleaver 55 that performs group-wise deinterleaving.

<LDPC Decoding>

The LDPC decoding performed by the LDPC decoder 166 in Figure 127 will now be explained in further detail.

As described above, in the LDPC decoder 166 in FIG. 127, LDPC decoding of an LDPC code that has been subjected to block deinterleaving and group-wise deinterleaving from the group-wise deinterleaver 55 and has not been subjected to parity deinterleaving is performed using a transformed check matrix obtained by performing at least column permutation equivalent to parity interleaving on the type B check matrix H used for LDPC encoding by the LDPC encoder 115 in FIG. 8, or a transformed check matrix (FIG. 29) obtained by performing row permutation on the type A check matrix (FIG. 27).

Here, a method of LDPC decoding has been proposed that uses a conversion check matrix to perform LDPC decoding, making it possible to suppress the circuit size while keeping the operating frequency within a fully feasible range (see, for example, Patent No. 4224777).

First, we will explain the previously proposed LDPC decoding using a conversion check matrix with reference to Figures 130 to 133.

Figure 130 shows an example of a check matrix H for an LDPC code with a code length N of 90 and a coding rate of 2/3.

Note that in Figure 130 (as well as Figures 131 and 132 described below), 0 is represented by a period (.).

In the check matrix H in Figure 130, the parity matrix has a staircase structure.

Figure 131 shows the check matrix H' obtained by applying the row permutation of equation (11) and the column permutation of equation (12) to the check matrix H in Figure 130.

Line replacement: 6s+t+1st line → 5t+s+1st line
...(11)

Column permutation: 6x+y+column 61 → 5y+x+column 61
...(12)

However, in formulas (11) and (12), s, t, x, and y are integers in the ranges 0≦s<5, 0≦t<6, 0≦x<5, and 0≦t<6, respectively.

According to the row permutation of equation (11), the 1st, 7th, 13th, 19th, and 25th lines, which have a remainder of 1 when divided by 6, are substituted with the 1st, 2nd, 3rd, 4th, and 5th lines, respectively, and the 2nd, 8th, 14th, 20th, and 26th lines, which have a remainder of 2 when divided by 6, are substituted with the 6th, 7th, 8th, 9th, and 10th lines, respectively.

In addition, according to the column permutation of equation (12), for columns 61 and onwards (parity matrix), columns 61, 67, 73, 79, and 85, which have a remainder of 1 when divided by 6, are permuted to columns 61, 62, 63, 64, and 65, respectively, and columns 62, 68, 74, 80, and 86, which have a remainder of 2 when divided by 6, are permuted to columns 66, 67, 68, 69, and 70, respectively.

In this way, the matrix obtained by permuting rows and columns of the check matrix H in Figure 130 is the check matrix H' in Figure 131.

Here, even if row permutation is performed on the check matrix H, it does not affect the arrangement of the code bits of the LDPC code.

The column permutation in equation (12) corresponds to the parity interleaving described above, in which the K+qx+y+1th code bit is interleaved at the K+Py+x+1th code bit position, when the information length K is 60, the parallel factor P is 5, and the divisor q (=M/P) of the parity length M (30 in this case) is 6.

Therefore, the check matrix H' in Figure 131 is a transformed check matrix obtained by at least performing a column permutation to replace the K+qx+y+1-th column of the check matrix H in Figure 130 (hereinafter referred to as the original check matrix, as appropriate) with the K+Py+x+1-th column.

For the conversion check matrix H' of Figure 131, when the LDPC code of the original check matrix H of Figure 130 is multiplied by the same permutation as that of formula (12), a zero vector is output.That is, when the row vector c of the LDPC code (one code word) of the original check matrix H is obtained by carrying out the column permutation of formula (12) and expressing it as c', according to the nature of check matrix, Hc ^T becomes a zero vector, so H'c' ^T also becomes a zero vector.

From the above, the converted check matrix H' in Figure 131 is the check matrix of the LDPC code c' obtained by performing the column permutation of equation (12) on the LDPC code c of the original check matrix H.

Therefore, by performing the column permutation of equation (12) on the LDPC code c of the original check matrix H, and then decoding (LDPC decoding) the LDPC code c' after the column permutation using the converted check matrix H' in FIG. 131, and then performing the inverse permutation of the column permutation of equation (12) on the decoded result, it is possible to obtain the same decoding result as when the LDPC code of the original check matrix H is decoded using that check matrix H.

Figure 132 shows the conversion check matrix H' in Figure 131, spaced apart by 5x5 matrix units.

In FIG. 132, the conversion check matrix H' is expressed as a combination of a 5x5 (=PxP) unit matrix, which is the parallel factor P; a matrix in which one or more of the units in the unit matrix have been changed to zero (hereinafter, appropriately referred to as a quasi-unit matrix); a matrix in which a unit matrix or a quasi-unit matrix has been cyclically shifted (hereinafter, appropriately referred to as a shift matrix); a sum of two or more of a unit matrix, a quasi-unit matrix, or a shift matrix (hereinafter, appropriately referred to as a sum matrix); and a 5x5 zero matrix.

The conversion check matrix H' in FIG. 132 can be said to be composed of a 5x5 unit matrix, quasi-unit matrix, shift matrix, sum matrix, and 0 matrix. Therefore, these 5x5 matrices (unit matrix, quasi-unit matrix, shift matrix, sum matrix, and 0 matrix) that compose the conversion check matrix H' will be referred to as constituent matrices below, where appropriate.

To decode an LDPC code of a check matrix represented by a P×P constituent matrix, an architecture that simultaneously performs P check node operations and variable node operations can be used.

Figure 133 is a block diagram showing an example of the configuration of a decoding device that performs such decoding.

In other words, FIG. 133 shows an example of the configuration of a decoding device that decodes an LDPC code using the transformed check matrix H' in FIG. 132 obtained by performing at least the column permutation of equation (12) on the original check matrix H in FIG. 130.

The decoding device of FIG. 133 comprises an edge data storage memory 300 consisting of six FIFOs ₃₀₀₁ to ₃₀₀₆ , a selector 301 which selects the FIFOs ₃₀₀₁ to ₃₀₀₆ , a check node calculation unit 302, two cyclic shift circuits 303 and 308, an edge data storage memory 304 consisting of ₁₈ FIFOs ₃₀₄₁ to 30418, a selector ₃₀₅ which selects the FIFOs 3041 to ₃₀₄₁₈ , a received data memory 306 which stores received data, a variable node calculation unit 307, a decoded word calculation unit 309, a received data rearrangement unit 310, and a decoded data rearrangement unit 311.

First, we will explain how data is stored in edge data storage memories 300 and 304.

The edge data storage memory 300 is composed of six FIFOs ₃₀₀₁ to ₃₀₀₆ , which is the number of rows of the conversion check matrix H' in Fig. 132, 30, divided by the number of rows of the constituent matrix (parallel factor P), 5. The FIFO _300y (y = 1, 2, ..., 6) is composed of a storage area with a plurality of stages, and the storage area of each stage is capable of simultaneously reading and writing messages corresponding to five edges, which are the number of rows and columns (parallel factor P) of the constituent matrix. The number of stages of the storage area of the FIFO _300y is 9, which is the maximum number of 1s (Hamming weight) in the row direction of the conversion check matrix in Fig. 132.

In FIFO 300 ₁ , data corresponding to the position of 1 from the first row to the fifth row of the conversion check matrix H' in FIG. 132 (message v _i from variable node) is stored in a form in which each row is packed horizontally (ignoring 0). That is, if the jth row and the ith column are represented as (j, i), the first-stage storage area of FIFO 300 ₁ stores data corresponding to the position of 1 in the 5×5 unit matrix (1,1) to (5,5) of the conversion check matrix H'. The second-stage storage area stores data corresponding to the position of 1 in the shift matrix (the shift matrix that cyclically shifts the 5×5 unit matrix to the right by three) from (1,21) to (5,25) of the conversion check matrix H'. Similarly, data is stored in the third to eighth-stage storage areas in association with the conversion check matrix H'. Then, in the memory area of the 9th stage, data corresponding to the positions of 1 in the shift matrix from (1,86) to (5,90) of the conversion check matrix H' (a shift matrix in which the 1 in the first row of a 5 x 5 unit matrix is replaced with 0 and cyclically shifted by one position to the left) is stored.

_FIFO3002 stores data corresponding to the position of 1 from the 6th row to the 10th row of the conversion check matrix H' in Fig. 132. That is, the first-stage storage area of _FIFO3002 stores data corresponding to the position of 1 of the first shift matrix that constitutes the sum matrix of (6,1) to (10,5) of conversion check matrix H' (the sum matrix is the first shift matrix that cyclically shifts a 5x5 unit matrix to the right by one place and the second shift matrix that cyclically shifts to the right by two places).In addition, the second-stage storage area stores data corresponding to the position of 1 of the second shift matrix that constitutes the sum matrix of (6,1) to (10,5) of conversion check matrix H'.

That is, for a constituent matrix with a weight of 2 or more, when the constituent matrix is expressed as a sum of a P×P unit matrix with a weight of 1, a quasi-unit matrix in which one or more of the 1 elements of the unit matrix have become 0, or a shift matrix obtained by cyclically shifting a unit matrix or a quasi-unit matrix, data corresponding to the position of 1 in the unit matrix, quasi-unit matrix, or shift matrix with a weight of 1 (messages corresponding to branches belonging to the unit matrix, quasi-unit matrix, or shift matrix) is stored at the same address (the same FIFO among FIFOs ₃₀₀₁ to ₃₀₀₆ ).

Then, data is stored in the memory areas from the third to ninth rows in association with the conversion check matrix H'.

Similarly, FIFOs ₃₀₀₃ to ₃₀₀₆ store data in association with the conversion check matrix H'.

The edge data storage memory 304 is composed of 18 FIFOs ₃₀₄₁ to ₃₀₄₁₈ , which is obtained by dividing the number of columns of the conversion check matrix H', 90, by the number of columns of the constituent matrix (parallel factor P), 5. The FIFOs _304x (x=1, 2, ..., 18) are composed of storage areas with a plurality of stages, and the storage area of each stage is capable of simultaneously reading and writing messages corresponding to five edges, which are the number of rows and columns of the constituent matrix (parallel factor P).

In FIFO 304 ₁ , data corresponding to the positions of 1 from the first column to the fifth column of the conversion check matrix H' in FIG. 132 (message u _j from check node) is stored in a form in which each column is packed vertically (ignoring 0). That is, in the first-stage storage area of FIFO 304 ₁ , data corresponding to the positions of 1 of the 5×5 unit matrix from (1,1) to (5,5) of the conversion check matrix H' is stored. In the second-stage storage area, data corresponding to the positions of 1 of the first shift matrix constituting the sum matrix from (6,1) to (10,5) of the conversion check matrix H' (the sum matrix being the sum of the first shift matrix obtained by cyclically shifting the 5×5 unit matrix to the right by one place and the second shift matrix obtained by cyclically shifting the 5×5 unit matrix to the right by two places) is stored. In addition, in the third-stage storage area, data corresponding to the positions of 1 of the second shift matrix constituting the sum matrix from (6,1) to (10,5) of the conversion check matrix H' is stored.

That is, for a constituent matrix with a weight of 2 or more, when the constituent matrix is expressed as a sum of a P×P unit matrix with a weight of 1, a quasi-unit matrix in which one or more of the 1 elements of the unit matrix have become 0, or a shift matrix obtained by cyclically shifting a unit matrix or a quasi-unit matrix, data corresponding to the position of 1 in the unit matrix, quasi-unit matrix, or shift matrix with a weight of 1 (messages corresponding to branches belonging to the unit matrix, quasi-unit matrix, or shift matrix) is stored at the same address (the same FIFO among FIFOs _304-1 to _304-18 ).

Similarly, data is stored in the fourth and fifth storage areas in association with the transformed check matrix H'. The number of storage areas in the FIFO ₃₀₄₁ is five, which is the maximum number of 1's (Hamming weights) in the row direction in the first to fifth columns of the transformed check matrix H'.

FIFOs ₃₀₄₂ and ₃₀₄₃ similarly store data in association with the conversion check matrix H', and each has a length (number of stages) of 5. FIFOs ₃₀₄₄ to ₃₀₄₁₂ similarly store data in association with the conversion check matrix H', and each has a length of 3. _{FIFOs 30413} to ₃₀₄₁₈ similarly store data in association with the conversion check matrix H', and each has a length of 2.

Next, we will explain the operation of the decoding device in Figure 133.

The edge data storage memory 300 is composed of six FIFOs ₃₀₀₁ to ₃₀₀₆ , and selects a FIFO from the FIFOs ₃₀₀₁ to ₃₀₀₆ to store data according to information (Matrix data) D312 indicating which row of the conversion check matrix H' in Fig. 132 the five messages D311 supplied from the cyclic shift circuit 308 in the previous stage belong to, and stores the five messages D311 in the selected FIFO in order. When reading data, the edge data storage memory 300 reads the five messages _D3001 in order from the FIFO ₃₀₀₁ and supplies them to the selector 301 in the next stage. After finishing reading the messages from the FIFO ₃₀₀₁ , the edge data storage memory 300 also reads messages in order from the FIFOs ₃₀₀₂ to ₃₀₀₆ and supplies them to the selector 301.

The selector 301 selects five messages from the FIFO from which data is currently being read out of the FIFOs 300 ₁ to 300 ₆ in accordance with the select signal D 301 , and supplies them to the check node calculation unit 302 as message D 302 .

The check node calculation unit 302 is made up of five check node calculators _302-1 to _302-5 , and performs check node calculation according to equation ( ₇ ) using messages D302 ( _D302-1 to D302-5) (messages v _i in equation (7)) supplied via the selector 301. The check node calculation unit 302 supplies five messages D303 ( _D303-1 to _D303-5 ) (messages u _j in equation (7)) obtained as a result of the check node calculation to the cyclic shift circuit 303.

The cyclic shift circuit 303 cyclically shifts the five messages _D303-1 to _D303-5 calculated by the check node calculation unit 302, based on information (Matrix data) D305 indicating how many cyclic shifts the original unit matrix (or quasi-unit matrix) of the corresponding edge in the converted parity check matrix H' has been performed, and supplies the result to the edge data storage memory 304 as a message D304.

The edge data storage memory 304 is made up of 18 FIFOs ₃₀₄₁ to ₃₀₄₁₈ , and selects a FIFO from FIFOs ₃₀₄₁ to ₃₀₄₁₈ to store data according to information D305 indicating which row of the conversion check matrix H' the five messages D304 supplied from the previous stage cyclic shift circuit 303 belong to, and stores the five messages D304 in the selected FIFO in sequence. When reading data, the edge data storage memory 304 reads five messages _D3061 from FIFO 3041 in sequence and supplies them to the selector 305 in the next stage. After finishing reading data from _{FIFO 3041} , the edge data storage memory 304 also reads messages from FIFOs ₃₀₄₂ to ₃₀₄₁₈ in sequence and supplies them to the selector 305.

The selector 305 selects five messages from the FIFO from which data is currently being read out of the FIFOs 304 ₁ to 304 ₁₈ in accordance with the select signal D 307 , and supplies them to the variable node calculation unit 307 and the decoded word calculation unit 309 as message D 308 .

Meanwhile, the received data rearrangement unit 310 rearranges the LDPC code D313 corresponding to the check matrix H in FIG. 130 received through the communication path 13 by performing column permutation according to equation (12), and supplies the result as received data D314 to the received data memory 306. The received data memory 306 calculates and stores the received LLR (log-likelihood ratio) from the received data D314 supplied from the received data rearrangement unit 310, and supplies the received LLR in groups of five as received values D309 to the variable node calculation unit 307 and the decoded word calculation unit 309.

The variable node calculation unit 307 consists of five variable node calculators ₃₀₇₁ to ₃₀₇₅ , and performs variable node calculations in accordance with equation (1) using messages D308 ( _D3081 to _D3085 ) (messages _uj in equation (1)) supplied through the selector 305 and five received values D309 (received values _u0i in equation (1)) supplied from the received data memory 306, and supplies messages D310 ( _D3101 to _D3105 ) (messages _vi in equation (1)) obtained as a result of the calculation to the cyclic shift circuit 308.

The cyclic shift circuit 308 cyclically shifts the messages _D3101 to _D3105 calculated by the variable node calculation unit 307 based on information indicating how many cyclic shifts the original unit matrix (or quasi-unit matrix) in the converted parity check matrix H' that the corresponding edge is obtained by, and supplies the result to the edge data storage memory 300 as a message D311.

By performing one cycle of the above operations, one decoding of the LDPC code (variable node calculation and check node calculation) can be performed. After the decoding device in FIG. 133 decodes the LDPC code a predetermined number of times, the decoded word calculation unit 309 and the decoded data rearrangement unit 311 calculate and output the final decoding result.

That is, the decoded word calculation unit 309 is made up of five decoded word calculators ₃₀₉₁ to ₃₀₉₅ , and uses the five messages D308 ( _D3081 to D3085) (messages _uj in equation ( ₅ )) output by the selector 305 and five received values D309 (received values _u0i in equation (5)) supplied from the received data memory 306 to calculate a decoding result (decoded word) based on equation (5) as the final stage of multiple decoding operations, and supplies the resulting decoded data D315 to the decoded data rearrangement unit 311.

The decoded data rearrangement unit 311 rearranges the order of the decoded data D315 supplied from the decoded word calculation unit 309 by performing the inverse permutation of the column permutation in equation (12), and outputs the final decoded result D316.

As described above, by performing row permutation or column permutation or both on the parity check matrix (original parity check matrix) and converting it into a P×P unit matrix, a quasi-unit matrix in which one or more of the 1s in its elements are changed to 0, a shift matrix in which a unit matrix or a quasi-unit matrix is cyclically shifted, a unit matrix, a quasi-unit matrix, or a sum matrix which is the sum of multiple shift matrices, and a combination of P×P 0 matrices, that is, a parity check matrix (converted parity check matrix) that can be expressed as a combination of constituent matrices, it becomes possible to adopt an architecture for decoding LDPC codes in which check node operations and variable node operations are performed simultaneously on P nodes, the number of which is smaller than the number of rows and columns of the parity check matrix. When adopting an architecture in which node operations (check node operations and variable node operations) are performed simultaneously on P nodes, the number of which is smaller than the number of rows and columns of the parity check matrix, it is possible to suppress the operating frequency to a feasible range and perform a large number of repeated decodings, compared to when node operations are performed simultaneously on a number equal to the number of rows and columns of the parity check matrix.

The LDPC decoder 166 constituting the receiving device 12 in FIG. 127 performs LDPC decoding by simultaneously performing P check node operations and variable node operations, similar to the decoding device in FIG. 133, for example.

In other words, for the sake of simplicity, if the check matrix of the LDPC code output by the LDPC encoder 115 constituting the transmitting device 11 in FIG. 8 is, for example, the check matrix H shown in FIG. 130, in which the parity matrix has a staircase structure, the parity interleaver 23 of the transmitting device 11 performs parity interleaving to interleave the K+qx+y+1th code bit at the K+Py+x+1th code bit position, with the information length K set to 60, the parallel factor P set to 5, and the divisor q (=M/P) of the parity length M set to 6.

As described above, this parity interleaving corresponds to the column permutation in equation (12), so the LDPC decoder 166 does not need to perform the column permutation in equation (12).

For this reason, in the receiving device 12 of FIG. 127, as described above, the group-wise deinterleaver 55 supplies the LDPC decoder 166 with an LDPC code that has not been subjected to parity deinterleaving, that is, an LDPC code that has been subjected to the column permutation of equation (12), and the LDPC decoder 166 performs processing similar to that of the decoding device of FIG. 133, except that the column permutation of equation (12) is not performed.

That is, FIG. 134 is a diagram showing an example configuration of the LDPC decoder 166 in FIG. 127.

In FIG. 134, the LDPC decoder 166 is configured in the same manner as the decoding device in FIG. 133, except that the received data rearrangement unit 310 in FIG. 133 is not provided, and performs the same processing as the decoding device in FIG. 133, except that the column permutation in equation (12) is not performed, so a description thereof is omitted.

As described above, the LDPC decoder 166 can be configured without the received data rearrangement unit 310, so the size can be reduced compared to the decoding device of FIG. 133.

In addition, in Figures 130 to 134, for simplicity, the code length N of the LDPC code is set to 90, the information length K is set to 60, the parallel factor (number of rows and columns of the constituent matrix) P is set to 5, and the divisor q (= M/P) of the parity length M is set to 6, but the code length N, information length K, parallel factor P, and divisor q (= M/P) are not limited to the values mentioned above.

In other words, in the transmitting device 11 of FIG. 8, the LDPC encoder 115 outputs an LDPC code with, for example, a code length N of 64800, 16200, 69120, 17280, etc., an information length K of N-Pq (=N-M), a parallel factor P of 360, and a divisor q of M/P. The LDPC decoder 166 of FIG. 134 is applicable to LDPC decoding of such an LDPC code by simultaneously performing P check node operations and variable node operations.

In addition, if the parity portion of the decoded result is not required after the LDPC decoder 166 decodes the LDPC code and only the information bits of the decoded result are output, the LDPC decoder 166 can be configured without the decoded data rearrangement unit 311.

<Example of the configuration of block deinterleaver 54>

Figure 135 is a diagram explaining the block deinterleaving performed by the block deinterleaver 54 in Figure 128.

In block deinterleaving, the reverse process of the block interleaving performed by the block interleaver 25 described in FIG. 79 is performed, and the order of the code bits of the LDPC code is returned (restored) to the original order.

In other words, in block deinterleaving, for example, like block interleaving, the arrangement of the LDPC code bits is restored to the original arrangement by writing and reading the LDPC code into m columns, which is equal to the number of bits in the symbol m.

However, in block deinterleaving, the LDPC codes are written in the same order as the LDPC codes are read in block interleaving. Furthermore, in block deinterleaving, the LDPC codes are read in the same order as the LDPC codes are written in block interleaving.

That is, for part 1 of the LDPC code, as shown in FIG. 135, part 1 of the LDPC code, which is an m-bit symbol unit, is written in the row direction from the first row of all m columns. That is, the code bits of the LDPC code, which is an m-bit symbol, are written in the row direction.

The writing of part 1 in m-bit units is performed sequentially from the bottom row of m columns, and when the writing of part 1 is completed, part 1 is read from the top of the first column unit in the column downwards, from left to right, as shown in FIG. 135.

When reading out to the rightmost column is complete, as shown in FIG. 135, the process returns to the leftmost column, and part 1 of the second column unit is read out from the top to the bottom, proceeding from left to right toward the columns, and so on until part 1 of the LDPC code for one codeword is read out.

When reading of part 1 of the LDPC code of one code word is completed, for part 2, which is an m-bit symbol unit, the m-bit symbol unit is sequentially concatenated after part 1, and the symbol-based LDPC code is returned to the code bit arrangement of the original LDPC code of one code word (the LDPC code before block interleaving).

<Other configuration examples of bit deinterleaver 165>

Figure 136 is a block diagram showing another example configuration of the bit deinterleaver 165 in Figure 127.

In the figure, parts corresponding to those in Figure 128 are given the same reference numerals, and their explanation will be omitted below as appropriate.

In other words, the bit deinterleaver 165 in FIG. 136 is configured in the same way as in FIG. 128, except that a parity deinterleaver 1011 is newly provided.

In FIG. 136, the bit deinterleaver 165 is composed of a block deinterleaver 54, a group-wise deinterleaver 55, and a parity deinterleaver 1011, and performs bit deinterleaving of the code bits of the LDPC code from the demapper 164.

That is, the block deinterleaver 54 performs block deinterleaving (the reverse process of block interleaving) on the LDPC code from the demapper 164, which corresponds to the block interleaving performed by the block interleaver 25 of the transmitting device 11, that is, block deinterleaving that returns the positions of the code bits that have been swapped by the block interleaving to their original positions, and supplies the resulting LDPC code to the group-wise deinterleaver 55.

The group-wise deinterleaver 55 performs group-wise deinterleaving on the LDPC code from the block deinterleaver 54, which corresponds to the group-wise interleaving performed as a rearrangement process by the group-wise interleaver 24 of the transmitting device 11.

The LDPC code resulting from group-wise deinterleaving is supplied from group-wise deinterleaver 55 to parity deinterleaver 1011.

The parity deinterleaver 1011 performs parity deinterleaving (the inverse process of parity interleaving) on the code bits after group-wise deinterleaving in the group-wise deinterleaver 55, which corresponds to the parity interleaving performed by the parity interleaver 23 of the transmitting device 11, i.e., performs parity deinterleaving to return the code bits of the LDPC code whose order has been changed by parity interleaving to their original order.

The LDPC code obtained as a result of parity deinterleaving is supplied from the parity deinterleaver 1011 to the LDPC decoder 166.

Therefore, in the bit deinterleaver 165 of FIG. 136, the LDPC decoder 166 is supplied with an LDPC code that has been block deinterleaved, group-wise deinterleaved, and parity deinterleaved, i.e., an LDPC code obtained by LDPC encoding according to the check matrix H.

The LDPC decoder 166 performs LDPC decoding of the LDPC code from the bit deinterleaver 165 using the check matrix H used for LDPC encoding by the LDPC encoder 115 of the transmitting device 11.

That is, for the Type B method, the LDPC decoder 166 performs LDPC decoding of the LDPC code from the bit deinterleaver 165 using the check matrix H (of the Type B method) used for LDPC encoding by the LDPC encoder 115 of the transmitting device 11, or using a transformed check matrix obtained by performing at least column permutation equivalent to parity interleaving on the check matrix H. For the Type A method, the LDPC decoder 166 performs LDPC decoding of the LDPC code from the bit deinterleaver 165 using a check matrix (FIG. 28) obtained by performing column permutation on the check matrix (FIG. 27) (of the Type A method) used for LDPC encoding by the LDPC encoder 115 of the transmitting device 11, or a transformed check matrix (FIG. 29) obtained by performing row permutation on the check matrix (FIG. 27) used for LDPC encoding.

In FIG. 136, the LDPC decoder 166 is supplied with an LDPC code obtained by LDPC encoding according to the check matrix H from the bit deinterleaver 165 (the parity deinterleaver 1011). When the LDPC code is decoded using the check matrix H of the type B method used for LDPC encoding by the LDPC encoder 115 of the transmitting device 11, or the check matrix (FIG. 28) obtained by performing column permutation on the check matrix (FIG. 27) of the type A method used for LDPC encoding, the LDPC decoder 166 can be configured, for example, as a decoding device that performs LDPC decoding using a full serial decoding method in which the calculation of messages (check node messages, variable node messages) is performed sequentially for each node, or a decoding device that performs LDPC decoding using a full parallel decoding method in which the calculation of messages is performed simultaneously (in parallel) for all nodes.

In the LDPC decoder 166, when LDPC decoding of the LDPC code is performed using a conversion check matrix obtained by performing at least column permutation equivalent to parity interleaving on the check matrix H of the type B method used for LDPC encoding by the LDPC encoder 115 of the transmitting device 11, or a conversion check matrix (FIG. 29) obtained by performing row permutation on the check matrix H of the type A method used for LDPC encoding (FIG. 27), the LDPC decoder 166 is a decoding device with an architecture that simultaneously performs P (or a divisor of P other than 1) check node operations and variable node operations, and can be configured as a decoding device (FIG. 133) having a received data rearrangement unit 310 that rearranges the code bits of the LDPC code by performing column permutation similar to the column permutation (parity interleaving) for obtaining the conversion check matrix on the LDPC code.

In FIG. 136, for ease of explanation, the block deinterleaver 54 that performs block deinterleaving, the groupwise deinterleaver 55 that performs groupwise deinterleaving, and the parity deinterleaver 1011 that performs parity deinterleaving are configured separately, but two or more of the block deinterleaver 54, groupwise deinterleaver 55, and parity deinterleaver 1011 can be configured integrally, similar to the parity interleaver 23, groupwise interleaver 24, and block interleaver 25 of the transmitting device 11.

<Example of receiving system configuration>

Figure 137 is a block diagram showing a first example configuration of a receiving system to which the receiving device 12 can be applied.

In FIG. 137, the receiving system is composed of an acquisition unit 1101, a transmission path decoding processing unit 1102, and an information source decoding processing unit 1103.

The acquisition unit 1101 acquires a signal including an LDPC code obtained by LDPC-encoding at least LDPC target data such as program image data and audio data via a transmission path (communication path) (not shown), such as terrestrial digital broadcasting, satellite digital broadcasting, a CATV network, the Internet, or other networks, and supplies the signal to the transmission path decoding processing unit 1102.

Here, when the signal acquired by the acquisition unit 1101 is broadcast from a broadcasting station via terrestrial waves, satellite waves, a CATV (Cable Television) network, or the like, the acquisition unit 1101 is configured with a tuner, an STB (Set Top Box), or the like. Also, when the signal acquired by the acquisition unit 1101 is transmitted by multicast from a web server, such as IPTV (Internet Protocol Television), the acquisition unit 1101 is configured with a network I/F (Interface) such as a NIC (Network Interface Card), for example.

The transmission path decoding processing unit 1102 corresponds to the receiving device 12. The transmission path decoding processing unit 1102 performs a transmission path decoding process, which includes at least a process for correcting errors that occur in the transmission path, on the signal acquired by the acquisition unit 1101 via the transmission path, and supplies the resulting signal to the information source decoding processing unit 1103.

In other words, the signal acquired by the acquisition unit 1101 via the transmission path is a signal obtained by at least performing error correction coding to correct errors that occur on the transmission path, and the transmission path decoding processing unit 1102 performs transmission path decoding processing such as error correction processing on such a signal.

Here, examples of error correction coding include LDPC coding and BCH coding. Here, at least LDPC coding is used as the error correction coding.

In addition, the transmission path decoding process may include demodulation of modulated signals.

The information source decoding processing unit 1103 performs information source decoding processing on the signal that has been subjected to transmission path decoding processing, which includes at least a process of expanding compressed information to the original information.

In other words, the signal acquired by the acquisition unit 1101 via the transmission path may have undergone compression encoding to compress the information in order to reduce the amount of data such as images and audio. In such a case, the information source decoding processing unit 1103 performs information source decoding processing, such as a process of expanding the compressed information to the original information (expansion processing), on the signal that has undergone transmission path decoding processing.

Note that if the signal acquired by the acquisition unit 1101 via the transmission path has not been compression-encoded, the information source decoding processing unit 1103 does not perform processing to expand the compressed information back to the original information.

Here, the decompression process includes, for example, MPEG decoding. In addition to the decompression process, the transmission path decoding process may also include descrambling, etc.

In the receiving system configured as described above, the acquisition unit 1101 performs compression encoding such as MPEG encoding on data such as images and audio, and the signal that has been further subjected to error correction encoding such as LDPC encoding is acquired via the transmission path and supplied to the transmission path decoding processing unit 1102.

In the transmission path decoding processing unit 1102, the signal from the acquisition unit 1101 is subjected to a transmission path decoding process, for example, a process similar to that performed by the receiving device 12, and the resulting signal is supplied to the information source decoding processing unit 1103.

The information source decoding processing unit 1103 performs information source decoding processing such as MPEG decoding on the signal from the transmission path decoding processing unit 1102, and outputs the resulting image or sound.

The receiving system shown in Figure 137 as described above can be applied to, for example, a television tuner that receives television broadcasts as digital broadcasts.

The acquisition unit 1101, the transmission path decoding processing unit 1102, and the information source decoding processing unit 1103 can each be configured as an independent device (hardware (such as an IC (Integrated Circuit)) or a software module).

Furthermore, with regard to the acquisition unit 1101, the transmission path decoding processing unit 1102, and the information source decoding processing unit 1103, it is possible to configure a set of the acquisition unit 1101 and the transmission path decoding processing unit 1102, a set of the transmission path decoding processing unit 1102 and the information source decoding processing unit 1103, or a set of the acquisition unit 1101, the transmission path decoding processing unit 1102, and the information source decoding processing unit 1103 as a single independent device.

Figure 138 is a block diagram showing a second example configuration of a receiving system to which the receiving device 12 can be applied.

In the figure, parts corresponding to those in Figure 137 are given the same reference numerals, and their explanation will be omitted below as appropriate.

The receiving system in FIG. 138 is the same as that in FIG. 137 in that it has an acquisition unit 1101, a transmission path decoding processing unit 1102, and an information source decoding processing unit 1103, but differs from that in FIG. 137 in that an output unit 1111 is newly provided.

The output unit 1111 is, for example, a display device that displays images or a speaker that outputs audio, and outputs images, audio, etc. as signals output from the information source decoding processing unit 1103. That is, the output unit 1111 displays images or outputs audio.

The receiving system of Figure 138 as described above can be applied, for example, to a TV (television receiver) that receives television broadcasts as digital broadcasts, or a radio receiver that receives radio broadcasts.

If the signal acquired by the acquisition unit 1101 has not been subjected to compression encoding, the signal output by the transmission path decoding processing unit 1102 is supplied to the output unit 1111.

Figure 139 is a block diagram showing a third example configuration of a receiving system to which the receiving device 12 can be applied.

In the figure, parts corresponding to those in Figure 137 are given the same reference numerals, and their explanation will be omitted below as appropriate.

The receiving system in FIG. 139 is the same as that in FIG. 137 in that it has an acquisition unit 1101 and a transmission path decoding processing unit 1102.

However, the receiving system in FIG. 139 differs from that in FIG. 137 in that it does not include an information source decoding processing unit 1103 and instead includes a new recording unit 1121.

The recording unit 1121 records (stores) the signal (e.g., TS packets of MPEG TS) output by the transmission path decoding processing unit 1102 onto a recording (storage) medium such as an optical disk, a hard disk (magnetic disk), or a flash memory.

The receiving system shown in Figure 139 above can be applied to recorders that record television broadcasts.

In FIG. 139, the receiving system is configured to include an information source decoding processing unit 1103, and the signal after information source decoding processing is performed by the information source decoding processing unit 1103, i.e., the image and sound obtained by decoding, can be recorded by a recording unit 1121.

<An embodiment of a computer>

Next, the above-mentioned series of processes can be performed by hardware or software. When the series of processes is performed by software, the program that constitutes the software is installed on a general-purpose computer or the like.

Figure 140 shows an example configuration of one embodiment of a computer on which a program that executes the above-mentioned series of processes is installed.

The program can be pre-recorded on a hard disk 705 or ROM 703 as a recording medium built into the computer.

Alternatively, the program can be temporarily or permanently stored (recorded) on a removable recording medium 711 such as a flexible disk, a CD-ROM (Compact Disc Read Only Memory), an MO (Magneto Optical) disk, a DVD (Digital Versatile Disc), a magnetic disk, or a semiconductor memory. Such a removable recording medium 711 can be provided as a so-called package software.

The program can be installed on the computer from the removable recording medium 711 as described above, or it can be transferred wirelessly from a download site to the computer via an artificial satellite for digital satellite broadcasting, or transferred wired to the computer via a network such as a LAN (Local Area Network) or the Internet, and the computer can receive the program transferred in this way via the communication unit 708 and install it on the built-in hard disk 705.

The computer includes a built-in CPU (Central Processing Unit) 702. An input/output interface 710 is connected to the CPU 702 via a bus 701. When a command is input by a user through the input/output interface 710 by operating an input unit 707 consisting of a keyboard, mouse, microphone, etc., the CPU 702 executes a program stored in a ROM (Read Only Memory) 703 in accordance with the command. Alternatively, the CPU 702 loads into a RAM (Random Access Memory) 704 a program stored in a hard disk 705, a program transferred from a satellite or a network, received by a communication unit 708, and installed on the hard disk 705, or a program read from a removable recording medium 711 attached to a drive 709 and installed on the hard disk 705. As a result, the CPU 702 performs processing according to the above-mentioned flowchart or processing performed by the configuration of the above-mentioned block diagram. Then, the CPU 702 outputs the processing results from the output unit 706, which is composed of an LCD (Liquid Crystal Display) and a speaker, via the input/output interface 710, or transmits the results from the communication unit 708, or records the results on the hard disk 705, as necessary.

In this specification, the processing steps that describe a program for causing a computer to perform various processes do not necessarily have to be processed chronologically in the order described in the flowchart, and also include processes that are executed in parallel or individually (for example, parallel processing or object-based processing).

The program may be processed by one computer, or may be distributed among multiple computers. Furthermore, the program may be transferred to a remote computer for execution.

The embodiment of this technology is not limited to the above-mentioned embodiment, and various modifications are possible without departing from the spirit of this technology.

For example, the new LDPC code (its check matrix initial value table) and GW pattern described above can be used for satellite lines, terrestrial waves, cables (wired lines), and other communication paths 13 (FIG. 7). Furthermore, the new LDPC code and GW pattern can also be used for data transmission other than digital broadcasting.

In addition, in this specification, for ease of understanding, it has been stated that the LDPC encoder 115 (FIG. 8) performs encoding into an LDPC code based on a check matrix, but the check matrix and the check matrix initial value table are equivalent information, and encoding into an LDPC code based on a check matrix includes encoding into an LDPC code based on the check matrix initial value table. Similarly, in the LDPC decoder 166 (FIG. 127), decoding of an LDPC code based on a check matrix includes decoding of an LDPC code based on the check matrix initial value table.

Note that the effects described in this specification are merely examples and are not limiting, and other effects may also be present.

11 transmitter, 12 receiver, 23 parity interleaver, 24 group-wise interleaver, 25 block interleaver, 54 block deinterleaver, 55 group-wise deinterleaver, 111 mode adaptation/multiplexer, 112 padder, 113 BB scrambler, 114 BCH encoder, 115 LDPC encoder, 116 bit interleaver, 117 mapper, 118 time interleaver, 119 SISO/MISO encoder, 120 frequency interleaver, 121 BCH encoder, 122 LDPC encoder, 123 mapper, 124 frequency interleaver, 131 frame builder/resource allocation unit, 132 OFDM generation unit, 151 OFDM processing unit, 152 frame management unit, 153 frequency deinterleaver, 154 Demapper, 155 LDPC decoder, 156 BCH decoder, 161 Frequency deinterleaver, 162 SISO/MISO decoder, 163 Time deinterleaver, 164 Demapper, 165 Bit deinterleaver, 166 LDPC decoder, 167 BCH decoder, 168 BB descrambler, 169 Null deletion unit, 170 Demultiplexer, 300 Edge data storage memory, 301 Selector, 302 Check node calculation unit, 303 Cyclic shift circuit, 304 Edge data storage memory, 305 Selector, 306 Received data memory, 307 Variable node calculation unit, 308 Cyclic shift circuit, 309 Decoded word calculation unit, 310 Received data rearrangement unit, 311 Decoded data rearrangement unit, 601 Encoding processing unit, 602 Storage unit, 611 coding rate setting unit, 612 initial value table reading unit, 613 check matrix generation unit, 614 information bit reading unit, 615 coding parity calculation unit, 616 control unit, 701 bus, 702 CPU, 703 ROM, 704 RAM, 705 hard disk, 706 output unit, 707 input unit, 708 communication unit, 709 drive, 710 input/output interface, 711, removable recording medium, 1001 reverse exchange unit, 1002 memory, 1011 parity deinterleaver, 1101 acquisition unit, 1101 transmission path decoding processing unit, 1103 information source decoding processing unit, 1111 output unit, 1121 recording unit

Claims (4)

A coding step of performing LDPC coding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 6/16;
A group-wise interleaving step of performing group-wise interleaving on the LDPC code in units of 360-bit bit groups;
A mapping step of mapping the LDPC code to any one of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits,
In the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and the sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group
23 42 33 17 37 2 22 14 21 0 12 44 30 1 25 35 46 13 10 24 20 15 45 31 41 43 28 36 16 4 32 18 3 6 34 11 40 5 38 27 29 8 26 7 39 9 47 19
Interleaved in the sequence of
The check matrix is
A matrix A in the upper left corner of the check matrix, which has M1 rows and K columns and is represented by a predetermined value M1 and an information length K=N×r of the LDPC code;
A B matrix having a step structure adjacent to the right of the A matrix, the B matrix having M1 rows and M1 columns;
A Z matrix, which is a zero matrix adjacent to the right of the B matrix and has M1 rows and N-K-M1 columns;
A matrix C having N-M1 rows and K+M1 columns adjacent below the matrix A and the matrix B;
A matrix D, which is an identity matrix adjacent to the right of the matrix C, and has N-K-M1 rows and N-K-M1 columns;
The predetermined value M1 is 720,
The A matrix and the C matrix are represented by a check matrix initial value table,
The parity check matrix initial value table is a table representing positions of elements of 1 in the A matrix and the C matrix for every 360 columns,
416 437 444 1657 2662 4109 4405 6308 8251
75 498 687 3903 4582 7035 7650 7871 10382
394 419 474 3515 6708 7277 8703 9969 10489
167 289 612 1847 5277 5900 8326 8508 9462
196 439 620 2128 2375 2501 6902 9308 9552
154 495 623 5024 6241 8364 9996 10104 10346
230 329 661 879 1474 3222 4109 8079 8865
97 172 692 1018 1629 1752 3170 5930
359 377 712 6273 7131 7278 8292 10457
368 551 708 787 2891 6140 7195 9555
44 512 655 2196 6692 7975 8410 10727
27 94 611 5585 7258 8091 9867 10714
608 639 691 3560 6819 7492 7754 7916
46 115 214 2175 5986 7177 8589 10757
282 589 604 969 1856 2433 5742 8900
243 262 669 1330 1366 3339 5517 7517
62 392 651 4175 8349 8557 9192 10015
206 375 697 1449 2015 2390 3926 4428 5084 5236 5872 8486 9398 9997 10469
1079 1384 1664 2936 4618 5359 5455 5537 5726 5875 8044 8521 9746
791 1106 1497 1885 2682 3473 3716 4506 5671 5829 8388 8641 9454
This is the transmission method. A coding step of performing LDPC coding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 6/16;
A group-wise interleaving step of performing group-wise interleaving on the LDPC code in units of 360-bit bit groups;
A mapping step of mapping the LDPC code to any one of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits,
In the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and the sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group
23 42 33 17 37 2 22 14 21 0 12 44 30 1 25 35 46 13 10 24 20 15 45 31 41 43 28 36 16 4 32 18 3 6 34 11 40 5 38 27 29 8 26 7 39 9 47 19
Interleaved in the sequence of
The check matrix is
A matrix A in the upper left corner of the check matrix, which has M1 rows and K columns and is represented by a predetermined value M1 and an information length K=N×r of the LDPC code;
A B matrix having a step structure adjacent to the right of the A matrix, the B matrix having M1 rows and M1 columns;
A Z matrix, which is a zero matrix adjacent to the right of the B matrix and has M1 rows and N-K-M1 columns;
A matrix C having N-M1 rows and K+M1 columns adjacent below the matrix A and the matrix B;
A matrix D, which is an identity matrix adjacent to the right of the matrix C, and has N-K-M1 rows and N-K-M1 columns;
The predetermined value M1 is 720,
The A matrix and the C matrix are represented by a check matrix initial value table,
The parity check matrix initial value table is a table representing positions of elements of 1 in the A matrix and the C matrix for every 360 columns,
416 437 444 1657 2662 4109 4405 6308 8251
75 498 687 3903 4582 7035 7650 7871 10382
394 419 474 3515 6708 7277 8703 9969 10489
167 289 612 1847 5277 5900 8326 8508 9462
196 439 620 2128 2375 2501 6902 9308 9552
154 495 623 5024 6241 8364 9996 10104 10346
230 329 661 879 1474 3222 4109 8079 8865
97 172 692 1018 1629 1752 3170 5930
359 377 712 6273 7131 7278 8292 10457
368 551 708 787 2891 6140 7195 9555
44 512 655 2196 6692 7975 8410 10727
27 94 611 5585 7258 8091 9867 10714
608 639 691 3560 6819 7492 7754 7916
46 115 214 2175 5986 7177 8589 10757
282 589 604 969 1856 2433 5742 8900
243 262 669 1330 1366 3339 5517 7517
62 392 651 4175 8349 8557 9192 10015
206 375 697 1449 2015 2390 3926 4428 5084 5236 5872 8486 9398 9997 10469
1079 1384 1664 2936 4618 5359 5455 5537 5726 5875 8044 8521 9746
791 1106 1497 1885 2682 3473 3716 4506 5671 5829 8388 8641 9454
A receiving device comprising a decoding unit that decodes the LDPC code obtained from data transmitted by the transmission method. A coding unit that performs LDPC coding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 6/16;
A group-wise interleaving unit that performs group-wise interleaving to interleave the LDPC code in units of 360-bit bit groups;
A mapping unit that maps the LDPC code to one of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits,
In the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and the sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group
23 42 33 17 37 2 22 14 21 0 12 44 30 1 25 35 46 13 10 24 20 15 45 31 41 43 28 36 16 4 32 18 3 6 34 11 40 5 38 27 29 8 26 7 39 9 47 19
Interleaved in the sequence of
The check matrix is
A matrix A in the upper left corner of the check matrix, which has M1 rows and K columns and is represented by a predetermined value M1 and an information length K=N×r of the LDPC code;
A B matrix having a step structure adjacent to the right of the A matrix, the B matrix having M1 rows and M1 columns;
A Z matrix, which is a zero matrix adjacent to the right of the B matrix and has M1 rows and N-K-M1 columns;
A matrix C having N-M1 rows and K+M1 columns adjacent below the matrix A and the matrix B;
A matrix D, which is an identity matrix adjacent to the right of the matrix C, and has N-K-M1 rows and N-K-M1 columns;
The predetermined value M1 is 720,
The A matrix and the C matrix are represented by a check matrix initial value table,
The parity check matrix initial value table is a table representing positions of elements of 1 in the A matrix and the C matrix for every 360 columns,
416 437 444 1657 2662 4109 4405 6308 8251
75 498 687 3903 4582 7035 7650 7871 10382
394 419 474 3515 6708 7277 8703 9969 10489
167 289 612 1847 5277 5900 8326 8508 9462
196 439 620 2128 2375 2501 6902 9308 9552
154 495 623 5024 6241 8364 9996 10104 10346
230 329 661 879 1474 3222 4109 8079 8865
97 172 692 1018 1629 1752 3170 5930
359 377 712 6273 7131 7278 8292 10457
368 551 708 787 2891 6140 7195 9555
44 512 655 2196 6692 7975 8410 10727
27 94 611 5585 7258 8091 9867 10714
608 639 691 3560 6819 7492 7754 7916
46 115 214 2175 5986 7177 8589 10757
282 589 604 969 1856 2433 5742 8900
243 262 669 1330 1366 3339 5517 7517
62 392 651 4175 8349 8557 9192 10015
206 375 697 1449 2015 2390 3926 4428 5084 5236 5872 8486 9398 9997 10469
1079 1384 1664 2936 4618 5359 5455 5537 5726 5875 8044 8521 9746
791 1106 1497 1885 2682 3473 3716 4506 5671 5829 8388 8641 9454
A transmitting device. A coding step of performing LDPC coding based on a check matrix of an LDPC code having a code length N of 17280 bits and a coding rate r of 6/16;
A group-wise interleaving step of performing group-wise interleaving on the LDPC code in units of 360-bit bit groups;
A mapping step of mapping the LDPC code to any one of 16 signal points of 2D-NUC (Non-Uniform Constellation) of 16QAM in units of 4 bits,
In the group-wise interleaving, the (i+1)th bit group from the beginning of the LDPC code is defined as bit group i, and the sequence of bit groups 0 to 47 of the 17280-bit LDPC code is defined as bit group
23 42 33 17 37 2 22 14 21 0 12 44 30 1 25 35 46 13 10 24 20 15 45 31 41 43 28 36 16 4 32 18 3 6 34 11 40 5 38 27 29 8 26 7 39 9 47 19
Interleaved in the sequence of
The check matrix is
A matrix A in the upper left corner of the check matrix, which has M1 rows and K columns and is represented by a predetermined value M1 and an information length K=N×r of the LDPC code;
A B matrix having a step structure adjacent to the right of the A matrix, the B matrix having M1 rows and M1 columns;
A Z matrix, which is a zero matrix adjacent to the right of the B matrix and has M1 rows and N-K-M1 columns;
A matrix C having N-M1 rows and K+M1 columns adjacent below the matrix A and the matrix B;
A matrix D, which is an identity matrix adjacent to the right of the matrix C, and has N-K-M1 rows and N-K-M1 columns;
The predetermined value M1 is 720,
The A matrix and the C matrix are represented by a check matrix initial value table,
The parity check matrix initial value table is a table representing positions of elements of 1 in the A matrix and the C matrix for every 360 columns,
416 437 444 1657 2662 4109 4405 6308 8251
75 498 687 3903 4582 7035 7650 7871 10382
394 419 474 3515 6708 7277 8703 9969 10489
167 289 612 1847 5277 5900 8326 8508 9462
196 439 620 2128 2375 2501 6902 9308 9552
154 495 623 5024 6241 8364 9996 10104 10346
230 329 661 879 1474 3222 4109 8079 8865
97 172 692 1018 1629 1752 3170 5930
359 377 712 6273 7131 7278 8292 10457
368 551 708 787 2891 6140 7195 9555
44 512 655 2196 6692 7975 8410 10727
27 94 611 5585 7258 8091 9867 10714
608 639 691 3560 6819 7492 7754 7916
46 115 214 2175 5986 7177 8589 10757
282 589 604 969 1856 2433 5742 8900
243 262 669 1330 1366 3339 5517 7517
62 392 651 4175 8349 8557 9192 10015
206 375 697 1449 2015 2390 3926 4428 5084 5236 5872 8486 9398 9997 10469
1079 1384 1664 2936 4618 5359 5455 5537 5726 5875 8044 8521 9746
791 1106 1497 1885 2682 3473 3716 4506 5671 5829 8388 8641 9454
a decoding step of decoding the LDPC code obtained from data transmitted by the transmitting method.

Images