JP6940989B2 - Encoder, Decoder, Transmitter and Receiver - Google Patents

Description

The present invention relates to the technical fields of satellite broadcasting and terrestrial broadcasting, as well as fixed communication and mobile communication, and more particularly to a digital data encoder, decoder, transmitter and receiver.

In the digital transmission method, a multi-value modulation method is often used so that more information can be transmitted in the frequency bandwidth available for each service. In order to improve the frequency utilization efficiency, it is effective to increase the number of bits (modulation order) allocated to one symbol of the modulated signal, but the relationship between the upper limit of the information speed that can be transmitted per 1 Hz of frequency and the signal-to-noise ratio is Limited by the Shannon limit.

In terrestrial digital broadcasting currently in use, information is corrected in a receiving device using an error correction code. By adding a redundant signal called a parity bit to the information to be sent, it is possible to control the redundancy (coding rate) of the signal and increase the resistance to noise. The error correction code and the modulation method are closely related, and the theoretical upper limit of the frequency utilization efficiency with respect to the signal-to-noise ratio is called the Shannon limit. The LDPC (Low Density Parity Check) code was proposed by Gallagher in 1962 as one of the powerful error correction codes having a performance approaching the Shannon limit (see, for example, Non-Patent Document 1).

The LDPC code is a linear code defined by a very sparse check matrix H (the check matrix elements consist of 0s and 1s and the number of 1s is very small).

The LDPC code is a powerful error correction code that can obtain transmission characteristics approaching the Shannon limit by increasing the code length and using an appropriate inspection matrix, and is the transmission of 4K / 8K Super Hi-Vision satellite broadcasting, which is a next-generation broadcasting service. The LDPC code is also used in ARIB STD-B44 (hereinafter referred to as an advanced satellite broadcasting system; see, for example, Non-Patent Document 2) that defines the system. By combining multi-value modulation and strong error correction codes such as LDPC codes, transmission with higher frequency utilization efficiency has become possible.

Taking the advanced satellite broadcasting system as an example, the code length of the LDPC code in this system is composed of forward error correction (FEC) frames and is 44,880 bits, which is the BPSK limit (the signal point arrangement is BPSK). It has been shown that the performance is within about 1 dB from the (theoretical upper limit of the frequency utilization efficiency with respect to the signal-to-noise ratio) in the case of (see, for example, Non-Patent Document 3).

Further, in the advanced satellite broadcasting system, the LDPC coding rates are 41/120 (≈1/3), 49/120 (≈2 / 5), 61/120 (≈1/2), 73/120 (≈1/2). 3/5), 81/120 (≈2/3), 89/120 (≈3/4), 93/120 (≈7/9), 97/120 (≈4/5), 101/120 (≈) Eleven types of 5/6), 105/120 (≈7 / 8), and 109/120 (≈9 / 10) are defined.

R. G Gallager, “Low Density Parity Check Codes,” in Research Monograph series Cambridge, MIT Press, 1963 "Transmission method standard for advanced broadband satellite digital broadcasting ARIB STD-B44 2.1 version, revised on March 25, 2016, Association of Radio Industries and Businesses (ARIB) Suzuki et al., "Design of LDPC Code for Advanced BS Digital Broadcasting", Journal of Video Information Media Society, General Incorporated Association Video Information Media Society, Video Information Media vol.62, No.12, December 1, 2008, pp.1997 -2004

Recently, in addition to the current 2K service by satellite and terrestrial broadcasting and 4K / 8K Super Hi-Vision by satellite broadcasting, it is expected to newly provide 4K / 8K Super Hi-Vision by terrestrial broadcasting (hereinafter, next-generation terrestrial broadcasting). However, 4K / 8K Super Hi-Vision (hereinafter, 4K / 8K) has a huge amount of information, and in order to maintain a sufficiently high service time rate and build a next-generation terrestrial broadcasting network, noise due to a poor propagation environment is required. A sufficiently high transmission power that is not buried is required. In the case of satellite broadcasting, non-linear distortion in satellite repeaters and power reduction due to rainfall attenuation are the main signal deterioration factors, but in terrestrial broadcasting, signal deterioration peculiar to terrestrial propagation such as multipath fading and urban noise occurs. appear. Therefore, as the basic performance of the error correction code in the next-generation terrestrial broadcasting, it is required to have a very high error correction capability that approaches the Shannon limit as much as possible by applying the LDPC code having a long code length. Furthermore, since the balance between broadcast quality and service time rate differs depending on the broadcaster, the selection of information bit rate can be flexibly changed by switching between multiple coding rates in a timely manner. It is desirable to prepare options equal to or better than the method.

As options for the coding rate in next-generation terrestrial broadcasting, the code length is 69120 bits, and the coding rate is 2/16, 3/16, 4/16, 5/16, 6/16, 7/16, 8 /. A total of 13 types of 16, 9/16, 10/16, 11/16, 12/16, 13/16, and 14/16 are being studied. While this code rate number is a sufficiently wider choice than the 11 types adopted in the advanced satellite broadcasting system, it is necessary to design an LDPC code check matrix having performance close to the Shannon limit for each code rate. be. Therefore, there is a need for a technique for making the inspection matrix optimized for the code rate, taking into account the occurrence of signal deterioration peculiar to terrestrial broadcasting in terrestrial broadcasting.

The present invention applies an LDPC code as an error correction code for terrestrial broadcasting and improves its performance with respect to an LDPC coding rate of 7/16, and is a digital data encoder, decoder, and transmitter having excellent noise resistance. And to provide a receiving device.

In the transmitting device and the receiving device according to the present invention, the encoder and the decoder according to the present invention include processing related to the LDPC code having an LDPC code rate of 7/16, and further effectively improve the characteristics of the LDPC code rate 7/16. The process related to the LDPC code is executed using the check matrix initial value table to be made. Further, in the transmitting device and the receiving device according to the present invention, the LDPC code inspection matrix using the inspection matrix initial value table having the LDPC code ratio of 7/16 is subjected to parity interleaving in order to generate a bit interleaving function. Configure to include a matrix.

Further, the encoder of the present invention is an encoder that LDPC-encodes digital data using an inspection matrix unique to each coding rate, and has a code length of 69120 bits and is predetermined for each coding rate. Using the initial value table of the inspection matrix as the initial value, one element of the sub-matrix corresponding to the information length corresponding to the coding rate of 7/16 is periodically arranged in the column direction with a plurality of types of cycles. An inspection matrix based on the inspection matrix initial value table having a coding rate of 7/16 is provided as a means for performing LDPC coding using an inspection matrix including a submatrix, and the inspection matrix based on the inspection matrix initial value table having a coding rate of 7/16 is periodic as the submatrix with the first number of cycles. A first submatrix in which one element is arranged in the column direction, and a second submatrix in which one element is periodically arranged in the column direction with a second cycle number different from the first cycle number. A third submatrix that is shifted in the row direction for each number of the first cycles and is subjected to parity interleaving by periodically arranging one element in the column direction at the number of the second cycles. Inspection of the coding rate 7/16 showing initial values when the first submatrix is a submatrix A, the second submatrix is a submatrix C, and the third submatrix is a submatrix D. The matrix initial value table (Table 1) is characterized in that it consists of the following table.

Further, the decoder of the present invention is characterized in that the data encoded by the encoder of the present invention is LDPC-decoded based on the inspection matrix.

Further, the transmitter of the present invention is characterized by including the encoder of the present invention.

Further, the receiving device of the present invention is characterized by including the decoding device of the present invention.

According to the present invention, it is possible to improve the performance of the LDPC code and improve the frequency utilization efficiency even in a very poor noise environment in terrestrial broadcasting.

It is a block diagram which shows only the main component of the transmission device in the transmission system of the LDPC coding rate 7/16 of one Example by this invention schematicly. It is a block diagram which shows only the main component of the receiving apparatus in the transmission system of the LDPC coding rate 7/16 of one Example by this invention. (A) and (b) are diagrams showing the configuration of a transmission frame in a transmission system having an LDPC coding rate of 7/16 according to an embodiment of the present invention, respectively. It is a figure which shows the inspection matrix H of LDPC coding rate 7/16 which concerns on this invention. It is a figure which shows the submatrix B of the LDPC coding rate 7/16 which concerns on this invention. It is a figure which shows the submatrix I of the LDPC coding rate 7/16 which concerns on this invention. It is a figure which shows the submatrix A of LDPC coding rate 7/16 which concerns on this invention. It is a figure which shows the submatrix C of LDPC coding rate 7/16 which concerns on this invention. It is a figure which shows the submatrix D of the LDPC coding rate 7/16 which concerns on this invention. It is a figure which shows the C / N vs. BER characteristic at the time of applying QPSK modulation of LDPC coding rate 7/16 which concerns on this invention. It is a figure which shows the difference from the Shannon limit at the time of applying QPSK modulation of LDPC coding rate 7/16 which concerns on this invention.

Hereinafter, the transmitting device 1 and the receiving device 2 in the transmission system of one embodiment according to the present invention will be described with reference to the drawings. The transmission system of one embodiment according to the present invention is composed of the transmitting device 1 shown in FIG. 1 and the receiving device 2 shown in FIG. 2 assuming a next-generation terrestrial broadcasting transmission system, and is an LDPC code used in the next-generation terrestrial broadcasting transmission system. Is optimized as a forward error correction code.

First, the transmission device 1 of the embodiment according to the present invention will be described with reference to FIG.

[Transmission device]
FIG. 1 is a block diagram schematically showing only the main components of the transmitter 1 according to the embodiment of the present invention. The transmission device 1 includes a frame generation unit 111, an energy diffusion unit 112, a BCH coding unit 113, an LDPC coding unit 114, and a modulation unit 115, and when transmitting an input bit string of a main signal, FIG. A series of processing is performed from the generation of the signal of the indicated transmission frame to the generation of the modulated signal. Hereinafter, the LDPC coding unit 114 is also simply referred to as a encoder. Further, the transmission device 1 has a TMCC generation unit 12 as a means for generating a TMCC signal including parameters related to transmission such as a modulation method and a coding rate and transmitting the TMCC signal before the main signal. The TMCC generation unit 12 is connected to the main signal processing unit 11 that performs signal processing of the main signal by a configuration different from that of the main signal processing unit 11, and transmits the TMCC signal to the main signal generated from the transmission frame generation unit 111 by time division multiplexing. Therefore, it is possible to transmit the parameters related to transmission to the receiving device 2 independently of the main signal. Further, the TMCC generation unit 12 provides the LDPC coding unit 114 and the modulation unit 115, which will be described later, with the LDPC coding rate (hereinafter, also simply referred to as “coding rate”) designated by the TMCC signal and the modulation method. Has a function to specify. Hereinafter, each component of the transmission device 1 shown in FIG. 1 will be described.

The transmission frame generation unit 111 divides the input bit string of the main signal into a predetermined length based on the transmission frame configuration according to the LDPC coding rate, and generates a transmission frame that enables LDPC coding. In this example, with respect to the LDPC coding rate of 7/16, as shown in FIG. 3, the input bit string of the main signal is divided into 30240 bits as the information bit length, and is output to the subsequent functional block each time.

(Transmission frame configuration with LDPC coding rate of 7/16)
3 (a) and 3 (b) show the configuration of a transmission frame in a transmission system having an LDPC coding rate of 7/16 according to an embodiment of the present invention, respectively. In particular, FIG. 3A shows the configuration of the transmission frame when only the LDPC code having the LDPC coding rate of 7/16 is used as the error correction code, and FIG. 3B shows the error correction code as the error correction code. The configuration of the transmission frame in the case of using the BCH code as the external code and the concatenated code consisting of the LDPC code having the LDPC coding rate of 7/16 as the internal code is shown. The transmission frames shown in FIGS. 3A and 3B are assumed to be transmission frames based on the LDPC code used in the next-generation terrestrial broadcasting transmission system.

First, the transmission frame shown in FIG. 3A is composed of an information bit satisfying the LDPC coding rate of 7/16 and LDPC parity. The transmission device 1 of the embodiment according to the present invention encodes and modulates by using the transmission frame configuration shown in FIG. 3 (a). Then, the receiving device 2 of the embodiment according to the present invention (see FIG. 2; details will be described later) performs demodulation and decoding of the error correction code based on this transmission frame configuration.

Further, the transmission frame shown in FIG. 3B is composed of an information bit, BCH parity, and LDPC parity as a modification of FIG. 3A, and is the same as the transmission frame shown in FIG. 3A, according to the present invention. It is applicable to the transmitting device 1 and the receiving device 2 of the above embodiment. In FIG. 3B, K_bch corresponds to the parity bit length of the BCH code. As an example of the external code, the case where the BCH code that can be used in the advanced satellite broadcasting system is applied is shown, and K_bch is 192 bits. BCH parity is basically treated as a part of information bits, and has a role of protecting minor bit errors that cannot be corrected by the LDPC code. When the LDPC parity lengths are equal, the correction capabilities of the LDPC codes are the same in FIGS. 3 (a) and 3 (b). However, since most of the error correction capability depends on the LDPC code, the transmission frame shown in FIG. 3A will be mainly described as a premise.

As shown in FIG. 3A, in the case of the LDPC coding rate of 7/16, the transmission frame length assuming the next-generation terrestrial broadcasting transmission method corresponds to 69120 bits, which is the LDPC code length. The 69120 bits are composed of an integral multiple of 360 and can be divided by 360 × 192. Further, since the information bit length is 30240 bits and 30240/69120 = 7/16, this transmission frame satisfies the LDPC coding rate of 7/16. Further, since the code length of 69120 bits is sufficiently longer than the LDPC code length of 44880 bits in the advanced satellite broadcasting system, an error correction capability closer to the Shannon limit can be expected.

As shown in FIG. 1, the energy diffusion unit 112 performs energy diffusion (bit randomization) on the output bit string of the transmission frame generation unit 111. This is realized by generating pseudo-random "1" and "0" patterns using the M sequence, and adding the pseudo-random "1" and "0" patterns to the data in the slot by MOD2. As a result, "1" or "0" is no longer continuous, so that synchronous reproduction can be stabilized in the receiving device 2 described later.

The BCH coding unit 113 is an error correction coding process provided as an external code as needed, and BCH coding is performed on predetermined data. The coding process of BCH coding can be the same as that specified in Non-Patent Document 2, and the details thereof will be omitted. When the configuration of the transmission frame shown in FIG. 3A is used, the processing of the BCH coding unit 113 is unnecessary in the transmission device 1 shown in FIG.

The LDPC coding unit 114 is input via predetermined data (or BCH coding unit 113) input via the energy diffusion unit 112 based on a predetermined coding rate specified by the TMCC signal generated by the TMCC generation unit 12. LDPC coding is applied to the BCH coded data). The details of LDPC coding using the LDPC code check matrix at the LDPC code rate 7/16 of the encoder (LDPC coding unit 114) according to the present invention will be described later.

The modulation unit 115 generates a modulation signal by performing quadrature modulation based on a predetermined modulation method specified by the TMCC signal generated by the TMCC generation unit 12. Modulation methods include, for example, BPSK (π / 2 shift BPSK (Binary Phase Shift Keying)), QPSK (Quadrature Phase Shift Keying), 8PSK, 16APSK (Amplitude and Phase-Shift Keying) (or 16QAM (Quadrature Amplitude Modulation)). , 32APSK (32QAM), 64QAM, 256QAM, 1024QAM and the like.

Next, the receiving device 2 of the embodiment according to the present invention will be described with reference to FIG.

[Receiver]
FIG. 2 is a block diagram schematically showing only the main components of the receiving device 2 according to the embodiment of the present invention. The receiving device 2 includes a demodulation unit 211, an LDPC decoding unit 212, a BCH decoding unit 213, a main signal processing unit 21 that performs signal processing of a main signal including an energy reverse diffusion unit 214, and a TMCC demodulation / decoding unit 22. I have.

The demodulation unit 211 demodulates the input modulated signal orthogonally, and outputs the demodulated IQ signal (orthogonal signal of the in-phase component I and the orthogonal phase component Q) to the LDPC decoding unit 212. The TMCC demodulation / decoding unit 22 demodulates / decodes the TMCC signal prior to the demodulation unit 211, and specifies the modulation method applied to the modulation of the main signal to the demodulation unit 211. Further, for the LDPC decoding unit 212 described later, the coding rate applied to the LDPC coding of the main signal is specified. The coding rate when the LDPC coding process is performed by the encoder (LDPC coding unit 114) according to the present invention corresponds to 7/16.

The LDPC decoding unit 212 is configured as a decoder for LDPC coding, and an IQ signal is input from the demodulating unit 211, and information on the modulation method and LDPC coding rate detected by the TMCC demodulating / decoding unit 22 is input. , Decoding according to a predetermined modulation method and LDPC coding rate. The details of LDPC decoding using the inspection matrix of the encoder (LDPC coding unit 114) according to the present invention will be described later.

The BCH decoding unit 213 decodes the BCH-encoded signal by the BCH coding unit 113 of the transmission device 1. When the configuration of the transmission frame shown in FIG. 3A is used, the processing of the BCH decoding unit 213 is unnecessary in the receiving device 2 shown in FIG.

In order to restore the process in which the pseudo-random code is added by MOD2 in the energy diffusion unit 112 of the transmission device 1, the energy back-diffusion unit 214 adds the same pseudo-random code again by MOD2 and performs the energy back-diffusion process. As a result, the signal processing unit 21 in the receiving device 2 restores the output bit string corresponding to the input bit string of the main signal transmitted from the transmitting device 1 and outputs the output bit string to the outside.

As described above, the transmitting device 1 and the receiving device 2 of the embodiment according to the present invention can freely change the modulation method and the coding rate by using a transmission frame corresponding to an error correction code using an LDPC code having a long code length. Can be combined with. Therefore, it is possible to efficiently transmit the MPEG-2 TS or other digital data stream to be transmitted as the main signal.

Next, each processing process of the encoder (LDPC coding unit 114) and the decoder (LDPC decoding unit 212) at the LDPC coding rate 7/16 according to the present invention will be described in order.

First, the processing process of the encoder (LDPC coding unit 114) of one embodiment will be described.

(Processing process of the encoder at LDPC coding rate 7/16)
The encoder (LDPC coding unit 114) of this embodiment generates an inspection matrix H divided into six regions by submatrixes A, B, C, D, I, and O, and uses this inspection matrix H as an inspection matrix H. It is used to generate LDPC code parity. FIG. 4 shows the basic configuration of the inspection matrix H at the LDPC coding rate of 7/16. The length of the inspection matrix H in the row direction corresponds to the LDPC code length, and the LDPC code length N = 69120 is set. Since the coding rate of this inspection matrix is 7/16, the length of the inspection matrix H in the column direction corresponds to the LDPC parity length, and the LDPC parity length P = 38880 bits.

In FIG. 4, the submatrixes A, C, and D are submatrixes constructed by using the inspection matrix initial value table shown in Table 1 above, and the LDGM structure (FIG. 5) is applied to the submatrix B. .. The row weight of the LDGM structure (the number of 1s in the row direction of the inspection matrix) is 1 for the first row, 2 for all the remaining row weights, and 2 for all columns (however, only the last column is 1). It is a matrix. The size of the submatrix B is 4680 bits in both the row direction and the column direction. Further, as the submatrix I, a diagonal matrix (FIG. 6) is applied. The row weights of the diagonal matrices are all 1. The size of the submatrix I is 34,200 bits in both the row direction and the column direction. The submatrix O corresponds to the zero matrix.

As shown in FIG. 7, the size of the submatrix A is composed of 4680 bits (rows) × 30240 bits (columns).

Further, as shown in FIG. 8, the size of the submatrix C is composed of 34200 bits (rows) × 30240 bits (columns).

Further, as shown in FIG. 9, the size of the submatrix D is composed of 34200 bits (rows) × 4680 bits (columns).

Since the size of these submatrixes is finite in any of the submatrixes A, C, and D, the position of 1 in the inspection matrix is calculated based on the following equation (1).
H _q-j = mod {(hi _i-j + mod ((q-1), 360)) x Q), P} (1)
Here, _{i of hii-j} is a row number of the check matrix initial value table, and _j of hii-j is a column number of the check matrix initial value table. H _q-j indicates the row number of 1 in the qth column of the inspection matrix H. J of H _q-j indicates the order of the number of elements of the column weight. Therefore, when the column weight is 9, j = 1 to 9. For q = 1, the first row of the check matrix initial value table is used. Also, mod (x, y) means the remainder of x divided by y. Q in the equation (1) is the number of cycles having a value determined for each coding rate, and Q is obtained by the equation (2).

Q = row size of each submatrix / 360 (2)

Therefore, in the LDPC coding rate of 7/16 of this embodiment, in the case of the submatrix A, Q = 13 (first cycle number Q1), in the case of the submatrix C, and the submatrix D, Q = 95 (second). The number of cycles Q2).

Hereinafter, a method of generating an inspection matrix H divided into six regions by submatrixes A, B, C, D, I, and O at an LDPC coding rate of 7/16 will be described more specifically.

First, the submatrix A (FIG. 7) will be described. In order to form the submatrix A, the encoder (LDPC coding unit 114) of the present embodiment reads a numerical value from a part of the inspection matrix initial value table shown in Table 1 described above, and reads a numerical value from a part of the inspection matrix initial value table to form a portion in the inspection matrix H. The position 1 in the region of the matrix A is periodically arranged. In the inspection matrix initial value table shown in Table 1, 97 numerical values are listed in the column direction and 11 numerical values are listed in the row direction. This numerical value corresponds to the first position (initial value) of 1 of the inspection matrix used in the submatrixes A, C and D. That is, the first position of 1 in the submatrix A, C, D in the inspection matrix H shown in FIG. 4 is specified by the numerical coordinates hi-j (numerical value) of the i-th row and the j-th column in Table 1. As an example, in FIG. 7, h1-1 (1433) corresponds to arranging 1 in the first column of the submatrix A in the 1433th row, and h1-2 (3551) corresponds to the first column of the submatrix A. Corresponds to placing eye 1 on line 3551. Further, h2-1 (894) arranges 1 in the 361st column of the submatrix A in the 894th row, and h2-2 (2650) arranges 1 in the 361st column of the submatrix A in the 2650th row. Corresponds to that.

Based on the above relationship, as shown in FIG. 7, the encoder (LDPC coding unit 114) of the present embodiment arranges 1 for every 360 columns of the submatrix A from the inspection matrix initial value table in Table 1. Read all of the numerical coordinates hi-j (numerical value) of 84 rows and j columns (maximum 3 columns) for specifying the row position to be performed, and first assign 1 to the position in the specified submatrix A, and this With respect to the position of 1 assigned first, 1 bit is shifted to the right in the row direction, and 1 is assigned to the position shifted downward in the column direction with the first number of cycles Q1 = 13 (13 bits). By repeating this, a sub-matrix A in the inspection matrix H is formed.

<Numerical coordinates hi-j (numerical value) for submatrix A of the inspection matrix initial value table in Table 1>
1st line: h1-1 (1433) to h1-2 (3551)
・ ・ ・ ・
Line 43: h43-1 (2580) to h1-2 (3067)
Line 44: h44-1 (878) to h1-3 (3513)
・ ・ ・ ・
Line 84: h84-1 (1831) to h84-3 (4649)

In this way, the numerical value of 84 rows (each row of these 84 rows corresponds to the first column of every 360 columns of the sub-matrix A) in the numerical coordinates hi-j (numerical value) for the sub-matrix A in Table 1 is one column. By reading every (the numerical value of each column corresponds to the first row position of each 360 columns of the submatrix A) and repeating the first cycle number Q1 = 13 shift as shown in FIG. 7, 360 × It is possible to specify the position of 1 of the sub-matrix A in the inspection matrix H corresponding to 84 = 30240 bits (column). The number of rows of the submatrix A is 360 × Q1 = 4680, and the size of the submatrix A is 30240 bits in the row direction and 4680 bits in the column direction.

Subsequently, the submatrix C (FIG. 8) will be described. In order to form the submatrix C, the encoder (LDPC coding unit 114) of the present embodiment reads a numerical value from a part of the inspection matrix initial value table shown in Table 1 above, and reads a numerical value from a part of the inspection matrix initial value table to form a portion in the inspection matrix H. The position 1 in the region of the matrix C is periodically arranged. In the inspection matrix initial value table shown in Table 1, 97 numerical values are listed in the column direction and 11 numerical values are listed in the row direction. The submatrix C differs from the submatrix A in the read position in the check matrix initial value table and the number of cycles.

As shown in FIG. 8, the encoder (LDPC coding unit 114) of the present embodiment specifies a row position for arranging 1 in every 360 columns of the sub-matrix C from the inspection matrix initial value table in Table 1. To read all of the numerical coordinates hi-j (numerical value) of 84 rows and j columns (maximum 9 columns), 1 is first assigned to the position in the specified submatrix C, and this first assigned 1 is assigned. By repeating the process of shifting 1 bit to the right in the row direction with respect to the position and assigning 1 to the position shifted downward in the column direction at the second cycle number Q2 = 95 (95 bits), in FIG. It constitutes a sub-matrix C in the inspection matrix H.

<Numerical coordinates hi-j (numerical value) for submatrix C of the inspection matrix initial value table in Table 1>
1st line: h1-3 (5930) to h1-11 (38303)
・ ・ ・ ・
Line 43: h43-3 (14591) to h43-11 (38176)
Line 44: h44-4 (8792) to h44-5 (30097)
・ ・ ・ ・
Line 84: h84-4 (4774) to h84-5 (24781)

In this way, the numerical value of 84 rows (each row of these 84 rows corresponds to the first column of every 360 columns of the sub-matrix C) in the numerical coordinates hi-j (numerical value) for the sub-matrix C in Table 1 is one column. By reading every (the numerical value of each column corresponds to the first row position of each 360 columns of the submatrix C) and repeating the second cycle number Q2 = 95 shift as shown in FIG. 8, 360 × It is possible to specify the position of 1 of the sub-matrix C in the inspection matrix H corresponding to 84 = 30240 bits (column). The number of rows of the submatrix C is 360 × Q2 = 34200, and the size of the submatrix C is 30240 bits in the row direction and 34200 bits in the column direction.

Subsequently, the submatrix D (FIG. 9) will be described. The encoder (LDPC coding unit 114) of this embodiment is a part of the inspection matrix initial value table shown in Table 1 above (in Table 1, rows 85 to 97) in order to form the submatrix D. The numerical value is read out from the line), and the position 1 in the region of the submatrix D in the inspection matrix H is periodically arranged. However, the submatrix D applies the same second cycle number Q2 = 95 as the submatrix C, but the difference from the submatrix C is that the first cycle number Q1 = is applied to the read cycle in the check matrix initial value table. The point is that parity interleaving is applied by using the bit shift in the row direction corresponding to 13.

As shown in FIG. 9, the encoder (LDPC coding unit 114) of the present embodiment specifies a row position for arranging 1 in every 360 columns of the sub-matrix D from the inspection matrix initial value table in Table 1. 13 rows and j columns (5 columns) for reading all the numerical coordinates hi-j (numerical values), 1 is first assigned to the position in the specified submatrix D, and this first assigned 1 position The first cycle number Q1 = 13 bits is shifted to the right in the row direction, and 1 is repeatedly assigned to the position shifted downward in the column direction at the second cycle number Q2 = 95 (95 bits). As a result, the sub-matrix D in the inspection matrix H in FIG. 4 is constructed.

<Numerical coordinates hi-j (numerical value) for submatrix D of the inspection matrix initial value table in Table 1>
Line 85: h85-1 (9157) to h85-5 (31607)
・ ・ ・ ・
Line 97: h97-1 (5876) to h97-5 (35330)

As described above, the method of reading the check matrix initial value table to which parity interleaving is applied is different from the method of reading the sub-matrix A and C, and is 13 in the numerical coordinates hi-j (numerical value) for the sub-matrix D in Table 1. Read the numerical value of each row (each row of these 13 rows corresponds to the first 13 columns of the submatrix D) column by column (the numerical value of each column corresponds to the row position of the first 13 columns of the submatrix D). , The reading of one row of the numerical coordinates hi-j (numerical value) for the submatrix D in Table 1 is set as one set. Then, as shown in FIG. 9, by repeating the right shift of Q1 = 13 bits corresponding to the number of first cycles and the downward shift of Q2 = 95 minutes corresponding to the number of second cycles 360 times, 360 times. It is possible to specify the position of 1 of the submatrix D in the inspection matrix H corresponding to × 13 = 4680 bits (column). The number of rows of the submatrix D is 360 × Q2 = 34200, and the size of the submatrix D is 4680 bits in the row direction and 34200 bits in the column direction.

That is, the relationship between the check matrix initial value table in the submatrix D shown in Table 1 and the column numbers in the check matrix H is shown below.
The numerical value in the 85th row of the check matrix initial value table is the first position of 1 in the 30241th column (that is, the first column of the submatrix D) in the check matrix H (in the first check matrix H repeated in the number of cycles Q1 and Q2). Line position) is described.
The numerical value in the 86th row of the check matrix initial value table is the first position of 1 in the 30242th column (that is, the second column of the submatrix D) in the check matrix H (in the first check matrix H repeated in the number of cycles Q1 and Q2). Line position) is described.
Similarly below
The numerical value in the 97th row of the check matrix initial value table is the first position of 1 in the 30253th column (that is, the 13th column of the submatrix D) in the check matrix H (in the first check matrix H repeated in the number of cycles Q1 and Q2). Line position) is described.

Then, in FIG. 9, the numerical value read from the 85th row of the inspection matrix initial value table is shifted by Q2 = 95 every 13 bits of Q1. By repeating this operation 360 times, the position of 1 in the submatrix D is determined for a total of 360 columns. Similarly, the numerical value read from the 86th row of the check matrix initial value table is also shifted by Q2 = 95 for every Q1 = 13 bits, and the position of 1 in the submatrix D is determined for a total of 360 columns. .. After that, by repeating the same process up to the 97th row of the last row, the position of 1 in the submatrix D corresponding to 360 columns × 13 sets = 4680 bits is determined. Therefore, the size of the submatrix D is 4680 bits in the row direction and 34200 bits in the column direction. In this way, by including the submatrix D to which the parity interleaving that shifts Q2 for each Q1 is applied in the inspection matrix H, the cycle 4 that occurs with the submatrix B that is connected to the submatrix D higher than the submatrix D occurs. It is possible to avoid the above and improve the decoding performance of the LDPC code. That is, the occurrence of an error floor is one of the causes of the deterioration of the transmission characteristics in the LDPC code, and as the cause of the error floor, an error occurs when the arrangement of 1 included in the inspection matrix H has, for example, many shape arrangements of the cycle 4. It is known that floors are more likely to occur. Therefore, as a means for solving this problem, an inspection matrix H including a submatrix D is used.

LDPC parity is calculated by the parity check equation (3) using the check matrix H, which is a set matrix of submatrixes A, B, C, D, I, and O at the LDPC coding rate of 7/16 obtained by the above processing. Is calculated. Since the information bit length is 30240 bits when the coding rate is 7/16, the parity calculation based on the LDGM structure is applied from the first row to the 4680th row of the check matrix H in the parity check equation. Then, from the 4681th line to the 38880th line, the parity calculation based on the diagonal structure is applied.

^{H · C T = 0 (3} )

The encoder (LDPC coding unit 114) of this embodiment uses 69120 bits as a basic unit, and 69120 has 1,2,3,4,5,6,8,10,11,12,15,16. It is a value that is divisible by a value such as. Therefore, when the encoder of this embodiment is applied as a functional block of the transmission device 1 shown in FIG. 1, it is possible to use a very diverse number of modulation multi-values, for example, BPSK (π / 2 shift BPSK). ), QPSK, 8PSK, 16APSK (16QAM), 32APSK (32QAM), 64QAM, 256QAM, 1024QAM, and the like. Therefore, the transmission device 1 of the present embodiment enables signal transmission that combines a very flexible modulation method and coding rate. The check matrix initial value table for the check matrix used for LDPC coding can be transmitted from the transmitting device 1 to the receiving device 2 as auxiliary information, or may be held in advance by the receiving device 2. .. Alternatively, the inspection matrix itself can be transmitted from the transmission device 1 to the reception device 2, or the inspection matrix itself may be held in advance by the reception device 2.

Subsequently, the processing process of the decoder (LDPC decoding unit 212) at the LDPC coding rate 7/16 of this embodiment will be described.

(Processing process of decoder at LDPC coding rate 7/16)
The decoder (LDPC decoding unit 212) of this embodiment performs LDPC code decoding processing using the inspection matrix H divided into six regions by the submatrix A, B, C, D, I, and O. .. For the sake of simplicity in the following description, the modulation method is BPSK.

The decoder (LDPC decoding unit 212) of this embodiment first calculates the log-likelihood ratio λ _n (n = 1 to 69120) _{based on the transmission symbol x n} and the reception symbol y _n. The log-likelihood ratio λ _n is a natural logarithm of the ratio of the certainty of the sending bit 0 and 1, and is expressed by the equation (4) using the _{transmitting symbol x n} and the receiving symbol y _n.

λ _n = ln {P (y _n | x _n = 0) / P (y _n | x _n = 1)} (4)

The LDPC decoding method by the sum-product decoding method or the like is performed using the log-likelihood ratio obtained by the equation (4) and the inspection matrix H (corresponding to FIG. 4) corresponding to the above-mentioned coding rate 7/16. The number of iterative decodings may be any value. Further, in LDPC decoding, various means such as a min-sum decoding method have been proposed in addition to the sum-product decoding method, and various methods for maximizing the likelihood ratio using a check matrix have been proposed in the present invention. It is applicable to such LDPC decoding.

FIG. 10 shows the C / N vs. BER characteristics (computer simulation) in QPSK modulation for the LDPC coding rate 7/16 according to the inspection matrix initial value table (Table 1). FIG. 10 shows the result after error correction by the BCH code (correction ability 12 bits) based on Non-Patent Document 2 (ARIB STD-B44), and the decoding algorithm is a sum-product decoding method (for example, Non-Patent Document). 1) was used. The number of decoding iterations of the sum-product decoding method is 50. FIG. 11 shows a comparison result of the Shannon limit C / N at the coding rate of 7/16 and the C / N at the BER = 1 × ^{10-7 point obtained from FIG.} From FIG. 11, it can be seen that by configuring the encoder, decoder, transmitter 1 and receiver 2 based on this inspection matrix, decoding performance approaching the Shannon limit can be obtained. Therefore, by adopting the inspection matrix H based on Table 1, it becomes possible to obtain a preferable transmission performance of less than 1 dB with respect to the Shannon limit, which was difficult in the current terrestrial digital broadcasting.

With respect to the above-described embodiment, a computer that functions as a encoder and a decoder, and a transmitter 1 and a receiver 2 is configured, and each means of the encoder and the decoder, and the transmitter 1 and the receiver 2 is made to function. The program for this can be preferably used. Specifically, at least a storage unit in which a control unit for controlling each means can be configured by a central processing unit (CPU) in a computer and a program necessary for operating each means is appropriately stored is at least. It can be configured with one memory. That is, by causing such a computer to execute the program by the CPU, the functions of the above-mentioned means can be realized. Further, a program for realizing the function of each means can be stored in a predetermined area of the above-mentioned storage unit (memory). Such a storage unit can be configured by a RAM or ROM inside the device, or can be configured by an external storage device (for example, a hard disk). Further, such a program can be configured as a part of software (stored in ROM or an external storage device) on an OS used in a computer. Further, the program for causing such a computer to function as each means can be recorded on a computer-readable recording medium. Further, each of the above-mentioned means may be configured as a part of hardware or software, and each of them may be combined and realized.

Although the above-described embodiment has been described as a representative example, it will be apparent to those skilled in the art that many modifications and substitutions can be made within the spirit and scope of the present invention. For example, as another error correction coding when combined with LDPC coding, other than BCH coding, not only block coding such as Reed-Solomon coding but also convolutional coding may be used, or other coding. LDPC coding may be combined. Therefore, the present invention should not be construed as being limited by the examples described above, but only by the claims.

The encoder and decoder, and the transmitter and receiver according to the present invention are useful in a transmission system in which a plurality of types of digital modulation schemes are time-divided and multiplexed when the code lengths of LDPC codes are different in various transmission schemes.

1 Transmitter 11 Main signal processing unit 111 Transmission frame generator 112 Energy diffusion unit 113 BCH coding unit 114 LDPC coding unit 115 Modulator 12 TMCC generator 2 Receiver 21 Main signal processing unit 211 Demodulation unit 212 LDPC decoding unit 213 BCH decoding unit 214 Energy reverse diffusion unit 22 TMCC demodulation / decoding unit

Claims (4)

An encoder that LDPC-encodes digital data using a check matrix unique to each coding rate.
With a code length of 69120 bits and a predetermined check matrix initial value table for each coding rate as the initial value, one element of the submatrix corresponding to the information length corresponding to the coding rate 7/16 is set in the column direction. A means for performing LDPC coding using an inspection matrix including a sub-matrix formed by periodically arranging and constructing a plurality of types of cycles is provided.
The inspection matrix based on the inspection matrix initial value table having a coding rate of 7/16 includes, as the sub-matrix, a first sub-matrix in which one element is periodically arranged in the column direction with the first number of cycles, and the above-mentioned sub-matrix. A second submatrix in which one element is periodically arranged in the column direction with a second cycle number different from the first cycle number, and the second submatrix shifted in the row direction for each first cycle number. Includes a third submatrix that has been subjected to parity interleaving by arranging elements of 1 periodically in the column direction in terms of the number of cycles.
Inspection of the coding rate 7/16 showing initial values when the first submatrix is the submatrix A, the second submatrix is the submatrix C, and the third submatrix is the submatrix D. The matrix initial value table is

Encoder characterized in that it consists of. A decoder according to claim 1 , wherein the data encoded by the encoder is LDPC-decoded based on the inspection matrix. A transmitter according to claim 1 , further comprising the encoder. A receiving device including the decoder according to claim 2.

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