ITTO20080154A1 - METHODS OF PROCESSING DIGITAL SIGNALS AND TRANSMISSION AND RECEPTION SYSTEMS THAT USE THEM - Google Patents

Description

"METHODS OF PROCESSING DIGITAL SIGNALS AND TRANSMISSION AND RECEPTION SYSTEMS THAT USE THEM"

SUMMARY

The present invention relates to methods of processing digital signals and transmission and reception systems which use them; the present invention is based on the use of LDPC codes, in particular the LDPC code with 3/5 coding rate, in combination with a QAM modulation, in particular the QAM256 modulation; in transmission, a bit permutation is performed (Demux) before the QAM constellation mapping function; in reception, the bit permutation is performed after the QAM constellation demapping function.

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DESCRIPTION

The present invention relates to digital signal processing methods and transmission and reception systems which use them.

The invention is intended to be applied above all, though not exclusively, to the reception and transmission of digital audio and video signals, and in particular to those relating to the broadcasting of second generation digital terrestrial television signals.

The second generation system for broadband satellite transmissions (DVB-S2) uses the LDPC (Low Density Parity Check) coding associated with the QPSK, 8PSK, 16APSK and 32APSK modulations to protect the signals from distortions of the transmission channel (Figure 1 ) which are suitable for transmission on non-linear channels, such as satellite channels. An exposition of the DVB-S2 standard and LDPC codes can be found for example in A. Morello, V. Mignone, "DVB-S2: The Second Generation Standard for Satellite Broad-band Services", Proceedings of the IEEE, Volume 94, Issue 1, Jan. 2006 Pages 210 - 227.

For a better exploitation of the potential of the codes, the DVB-S2 standard provides that between the LDPC encoder and the mapper on the constellations 8PSK, 16APSK and 32APSK an interlacer is interposed which allows a better association between the bits of the coded word and the bits carried by the points. of the constellation.

The interlacer defined in the DVB-S2 standard requires that the packet encoded at the output of the LDPC encoder (formed by a number of bits equal to 16200 or 64800, a number generally indicated with the "NFRAME" symbol) is written by columns in a matrix with N columns, where N is the number of bits carried by the constellation (N is 3 for 8PSK, 4 for 16APSK, 5 for 32APSK), and NFRAME / N rows (Figure 2), and is read by rows; the reading takes place from left to right for all the coding rates foreseen by the standard except for the 3/5 rate, where the reading takes place from right to left. The association to the points or coordinates of the constellations occurs as expressed in Figure 1.

Currently, it is planned to use the same coding scheme of the DVB-S2 standard, i.e. the same LDPC codes, but associated with modulations for the reception and transmission of digital audio and video signals relating to the broadcasting of second generation digital terrestrial television signals. QAM [Quadrature Amplitude Modulation]; in particular, the QPSK, 16QAM, 64QAM and 256QAM modulations are provided (Figure 3).

The Applicant has realized that, with the QAM modulations, the LDPC codes provide good performances, but not totally satisfactory in terms of the signal to noise ratio [SNR] necessary to reach the QEF [Almost Error Free] condition; as known, this condition corresponds to the case in which less than one error is received for each hour of program received.

The present invention has the general purpose of overcoming the problem mentioned above and, in particular, of associating in a better way the bits at the output of the LDPC encoder to the coordinates of the constellations of the QAM modulations; more particularly, the present invention deals with LDPC coding with 3/5 coding rate and with 256QAM modulation.

The aforesaid objects are achieved through the methods of processing digital signals and the transmission and reception systems having the characteristics set out in the appended claims which form an integral part of the present description.

The invention will now be described in detail in some of its preferred embodiments, given by way of non-restrictive example, with reference to the attached drawings, in which:

Figure 1 is a schematic representation of the QPSK, 8PSK, 16APSK and 32APSK constellations provided, among other things, by the DVB-S2 standard;

Figure 2 represents an explanatory diagram of the interlacer provided by the DVB-S2 standard, specifically the 8PSK modulation; Figure 3 is a schematic representation of the QPSK, 16QAM, 64QAM and 256QAM constellations applicable to the reception and transmission of audio and video signals relating to the broadcasting of second generation digital terrestrial television signals;

Figure 4 represents a very simplified block diagram of a modulating digital signal processing system according to the present invention;

Figure 5 represents a general explanatory diagram of the interlacer of Figure 4;

Figure 6 schematically represents the function performed by the “Demux” block of Figure 5 according to a first embodiment of the present invention;

Figure 7 schematically represents the function performed by the “Demux” block of Figure 5 according to a second embodiment of the present invention;

Figure 8 schematically represents the function performed by the “Demux” block of Figure 5 according to a third embodiment of the present invention;

Figure 9 schematically represents the function performed by the “Demux” block of Figure 5 according to a fourth embodiment of the present invention.

Figure 10 schematically represents the function performed by the “Demux” block of Figure 5 according to a fifth embodiment of the present invention.

Figure 4 schematically represents the procedure for associating the bits of the modulating information flow to the points or coordinates of the constellation of the QAM modulation.

The "Encoder" block receives the modulating information flow at its input and generates a coded information flow organized in packets consisting of NFRAME bits, equal to 64800 or 16200; the code used is the LDPC with 3/5 coding rate.

Within the "Interleaver" block, these packets are written in an interlacing matrix, of total NFRAME size; this matrix is made up of m × N columns and NFRAME / m × N rows.

The “Demux” block performs a permutation of the bits received as input from the “Interleaver” block; these bits are received by the interlacing matrix in groups of m × N at a time, where N is the number of bits carried by the constellation (N = 2 for the QPSK, N = 4 for the 16QAM, N = 6 for the 64QAM, N = 8 for 256QAM), and "m" is an integer greater than or equal to 1. The "Demux" block associates them in m groups of N bits, exchanges them according to pre-established schemes taking into account the type of modulation (ie the level QAM), the code and the type of transmission channel and provides them at the output.

The "Mapper" block associates the N-ple of bits at the output of the "Demux" block to the points or coordinates of the constellation, for example as indicated in Figure 3 for QAM modulations.

It is worth highlighting that the blocks represented in Figure 4 are only those essential to the understanding of the present invention; therefore, the presence of intermediate blocks must not be excluded, for example between the “Demux” block and the “Mapper” block, suitable for carrying out specific signal processing functions.

The present invention proposes particular permutation schemes that can be adopted for QAM modulations and LDPC codes with different coding rates as provided, for example, by the DVB-S2 standard in association with different types of interlacing.

The preferred embodiment of the present invention refers to the 256QAM modulation and to the LDPC code with coding rate 3/5.

The preferred embodiment of the present invention provides that an interlacer equal to or similar to that of the DVB-S2 standard (Figure 2) is used with a number of bits / columns depending on the type of QAM modulation levels.

According to a first example of implementation, a “Demux” block is used in which “m” is equal to 1 (ie 8 bits in the case of QAM256) and that therefore the rows of the matrix of the “Interleaver” block are read one at a time.

The N bits in input to the “Demux” block are permuted as specified in Figure 6 (first example of implementation), for the modulation 256QAM coded with a 3/5 rate. That is, given the N bits from b0 to b7 (in input to the block), the N bits carried by the 256QAM constellation from y0 to y7 (in output to the block) are determined as follows:

y0 = b0, y1 = b6, y2 = b2, y3 = b3, y4 = b4, y5 = b7, y6 = b1, y7 = b5

where b0 and y0 indicate the most significant bits [MSB] and b7 and y7 indicate the least significant bits [LSB].

Alternatively (second embodiment example), the present invention provides that a matrix "Interleaver" interleaver is used, made as a matrix with 2 × N columns and NFRAME / (2 × N) rows, written by columns from top to bottom , and read by lines, from left to right. In this case, the "Demux" block operates with m equal to 2. The 2 × N bits in input to the "Demux" block are permuted as specified in Figure 7, for the 256QAM modulation coded with a 3/5 rate, and associated with 2 consecutive symbols of the 256QAM modulation.

That is, given the 2 × N bits from b0 to b15, the 2 × N bits carried by the 256QAM constellation from y0 to y15 are determined as follows:

y0 = b0, y1 = b10, y2 = b7, y3 = b6, y4 = b13, y5 = b15, y6 = b3, y7 = b9,

y8 = b11, y9 = b1, y10 = b8, y11 = b5, y12 = b2, y13 = b14, y14 = b4, y15 = b12 where b0 and y0 indicate the most significant bits [MSB] and b15 and y15 the least significant bits [LSB] have been indicated.

To be precise, it is expected that bits from y0 to y7 are sent to the “Mapper” block first and then bits from y8 to y15.

Again in the case in which the "Demux" block operates with m equal to 2, there is another permutation that has proved to be advantageous (third example of implementation); the 2 × N bits in input to the “Demux” block are permuted as specified in Figure 8, for the 256QAM modulation coded with a 3/5 rate, and associated with 2 consecutive symbols of the 256QAM modulation.

That is, given the 2 × N bits from b0 to b15, the 2 × N bits carried by the 256QAM constellation from y0 to y15 are determined as follows:

y0 = b4, y1 = b6, y2 = b0, y3 = b2, y4 = b3, y5 = b10, y6 = b12, y7 = b14,

y8 = b7, y9 = b5, y10 = b8, y11 = b1, y12 = b11, y13 = b9, y14 = b15, y15 = b13

Again in the case in which the "Demux" block operates with m equal to 2, there is also a further permutation which has proved to be advantageous (fourth example of implementation); the 2 × N bits in input to the “Demux” block are permuted as specified in Figure 9, for the 256QAM modulation coded with a 3/5 rate, and associated with 2 consecutive symbols of the 256QAM modulation.

That is, given the 2 × N bits from b0 to b15, the 2 × N bits carried by the 256QAM constellation from y0 to y15 are determined as follows:

y0 = b0, y1 = b12, y2 = b4, y3 = b6, y4 = b8, y5 = b14, y6 = b2, y7 = b10,

y8 = b1, y9 = b13, y10 = b5, y11 = b7, y12 = b9, y13 = b15, y14 = b3, y15 = b11

Finally and always in the case in which the "Demux" block operates with m equal to 2, there is also a last permutation which has proved to be advantageous (fifth example of implementation); the 2 × N bits in input to the “Demux” block are permuted as specified in Figure 10, for the 256QAM modulation coded with a 3/5 rate, and associated with 2 consecutive symbols of the 256QAM modulation.

That is, given the 2 × N bits from b0 to b15, the 2 × N bits carried by the 256QAM constellation from y0 to y15 are determined as follows:

y0 = b4, y1 = b6, y2 = b0, y3 = b2, y4 = b3, y5 = b14, y6 = b12, y7 = b10,

y8 = b7, y9 = b5, y10 = b8, y11 = b1, y12 = b15, y13 = b9, y14 = b11, y15 = b13

The methods described above can advantageously be used in a digital signal transmission system based on the QAM256 modulator, in particular in a transmitter of digital audio and video signals for broadcasting digital terrestrial television signals.

As is evident for the skilled in the art, if the methods described above are applied in the transmission phase, inverse methods must be applied in the reception phase.

As is known, the transmission of television signals is carried out by radio frequency transmitters, while the reception of television signals is carried out by television receivers typically installed in the homes of users of the television service.

Claims (16)

CLAIMS 1. Method for processing digital signals to be sent to a modulator of the QAM type, said signals being encoded according to an LDPC code, characterized in that a bit permutation is performed before the constellation mapping function. Method according to claim 1, wherein said digital signals are audio and video, wherein said modulator is of the 256QAM type, wherein said signals are coded according to the LDPC code at 3/5 coding rate, and wherein said permutation of bits is carried out on words having a length of 8 bits or 16 bits or further multiples of 8 bits. 3. Method according to claim 1 or 2, wherein said permutation is carried out on words of 8 bits and consists in generating a word Y comprising in the order the bits y0 y1 y2 y3 y4 y5 y6 y7, starting from a word B comprising in the order the bits b0 b1 b2 b3 b4 b5 b6 b7, the bits y0 and b0 being respectively the most significant bits of the words Y and B and the bits y7 and b7 being respectively the least significant bits of the words Y and B, and in which: - y0 corresponds to b0, - y1 corresponds to b6, - y2 corresponds to b2, - y3 corresponds to b3, - y4 corresponds to b4, - y5 corresponds to b7, - y6 corresponds to b1, - y7 corresponds to b5. 4. Method according to claim 1 or 2, in which said permutation is carried out on words of 16 bits and consists in generating a word Y comprising in the order the bits y0 y1 y2 y3 y4 y5 y6 y7 y8 y9 y10 y11 y12 y13 y14 y15 , starting from a word B comprising in the order the bits b0 b1 b2 b3 b4 b5 b6 b7 b8 b9 b10 b11 b12 b13 b14 b15, the bits y0 and b0 being respectively the most significant bits of the words Y and B and the bits y15 and b15 being respectively the least significant bits of words Y and B, where: - y0 corresponds to b0, - y1 corresponds to b10, - y2 corresponds to b7, - y3 corresponds to b6, - y4 corresponds to b13, - y5 corresponds to b15, - y6 corresponds to b3, - y7 corresponds to b9, - y8 corresponds to b11, - y9 corresponds to b1, - y10 corresponds to b8, - y11 corresponds to b5, - y12 corresponds to b2, - y13 corresponds to b14, - y14 corresponds to b4, - y15 corresponds to b12. 5. Method according to claim 1 or 2, in which said permutation is carried out on words of 16 bits and consists in generating a word Y comprising in the order the bits y0 y1 y2 y3 y4 y5 y6 y7 y8 y9 y10 y11 y12 y13 y14 y15 , starting from a word B comprising in the order the bits b0 b1 b2 b3 b4 b5 b6 b7 b8 b9 b10 b11 b12 b13 b14 b15, the bits y0 and b0 being respectively the most significant bits of the words Y and B and the bits y15 and b15 being respectively the least significant bits of words Y and B, where: - y0 corresponds to b4, - y1 corresponds to b6, - y2 corresponds to b0, - y3 corresponds to b2, - y4 corresponds to b3, - y5 corresponds to b10, - y6 corresponds to b12, - y7 corresponds to b14, - y8 corresponds to b7, - y9 corresponds to b5, - y10 corresponds to b8, - y11 corresponds to b1, - y12 corresponds to b11, - y13 corresponds to b9, - y14 corresponds to b15, - y15 corresponds to b13. 6. Method according to claim 1 or 2, in which said permutation is carried out on words of 16 bits and consists in generating a word Y comprising in the order the bits y0 y1 y2 y3 y4 y5 y6 y7 y8 y9 y10 y11 y12 y13 y14 y15 , starting from a word B comprising in the order the bits b0 b1 b2 b3 b4 b5 b6 b7 b8 b9 b10 b11 b12 b13 b14 b15, the bits y0 and b0 being respectively the most significant bits of the words Y and B and the bits y15 and b15 being respectively the least significant bits of words Y and B, where: - y0 corresponds to b0, - y1 corresponds to b12, - y2 corresponds to b4, - y3 corresponds to b6, - y4 corresponds to b8, - y5 corresponds to b14, - y6 corresponds to b2, - y7 corresponds to b10, - y8 corresponds to b1, - y9 corresponds to b13, - y10 corresponds to b5, - y11 corresponds to b7, - y12 corresponds to b9, - y13 corresponds to b15, - y14 corresponds to b3, - y15 corresponds to b11. 7. Method according to claim 1 or 2, in which said permutation is carried out on words of 16 bits and consists in generating a word Y comprising in the order the bits y0 y1 y2 y3 y4 y5 y6 y7 y8 y9 y10 y11 y12 y13 y14 y15 , starting from a word B comprising in the order the bits b0 b1 b2 b3 b4 b5 b6 b7 b8 b9 b10 b11 b12 b13 b14 b15, the bits y0 and b0 being respectively the most significant bits of the words Y and B and the bits y15 and b15 being respectively the least significant bits of words Y and B, where: - y0 corresponds to b4, - y1 corresponds to b6, - y2 corresponds to b0, - y3 corresponds to b2, - y4 corresponds to b3, - y5 corresponds to b14, - y6 corresponds to b12, - y7 corresponds to b10, - y8 corresponds to b7, - y9 corresponds to b5, - y10 corresponds to b8, - y11 corresponds to b1, - y12 corresponds to b15, - y13 corresponds to b9, - y14 corresponds to b11, - y15 corresponds to b13. 8. Digital signal transmission system comprising a modulator of the QAM type, characterized in that it provides the method according to any one of claims 1 to 7. 9. Method for processing digital signals received by a demodulator of the QAM type, said signals being encoded according to an LDPC code, characterized in that after the constellation demapping function a bit permutation is carried out. Method according to claim 9, wherein said digital signals are audio and video, wherein said demodulator is of the 256QAM type, wherein said signals are coded according to the LDPC code at 3/5 coding rate, and wherein said permutation of bits is carried out on words having a length of 8 bits or 16 bits or further multiples of 8 bits. 11. Method according to claim 9 or 10, wherein said permutation is carried out on words of 8 bits and consists in generating a word B comprising in the order the bits b0 b1 b2 b3 b4 b5 b6 b7, starting from a word Y comprising in the order the bits y0 y1 y2 y3 y4 y5 y6 y7, the bits y0 and b0 being respectively the most significant bits of the words Y and B and the bits y7 and b7 being respectively the least significant bits of the words Y and B, and in which: - y0 corresponds to b0, - y1 corresponds to b6, - y2 corresponds to b2, - y3 corresponds to b3, - y4 corresponds to b4, - y5 corresponds to b7, - y6 corresponds to b1, - y7 corresponds to b5. Method according to claim 9 or 10, wherein said permutation is carried out on words of 16 bits and consists in generating a word B comprising in the order the bits b0 b1 b2 b3 b4 b5 b6 b7 b8 b9 b10 b11 b12 b13 b14 b15 , starting from a word Y comprising in the order the bits y0 y1 y2 y3 y4 y5 y6 y7 y8 y9 y10 y11 y12 y13 y14 y15, the bits y0 and b0 being respectively the most significant bits of the words Y and B and the bits y15 and b15 being respectively the least significant bits of words Y and B, where: - y0 corresponds to b0, - y1 corresponds to b10, - y2 corresponds to b7, - y3 corresponds to b6, - y4 corresponds to b13, - y5 corresponds to b15, - y6 corresponds to b3, - y7 corresponds to b9, - y8 corresponds to b11, - y9 corresponds to b1, - y10 corresponds to b8, - y11 corresponds to b5, - y12 corresponds to b2, - y13 corresponds to b14, - y14 corresponds to b4, - y15 corresponds to b12. 13. Method according to claim 9 or 10, wherein said permutation is carried out on words of 16 bits and consists in generating a word B comprising in the order the bits b0 b1 b2 b3 b4 b5 b6 b7 b8 b9 b10 b11 b12 b13 b14 b15 , starting from a word Y comprising in the order the bits y0 y1 y2 y3 y4 y5 y6 y7 y8 y9 y10 y11 y12 y13 y14 y15, the bits y0 and b0 being respectively the most significant bits of the words Y and B and the bits y15 and b15 being respectively the least significant bits of words Y and B, where: - y0 corresponds to b4, - y1 corresponds to b6, - y2 corresponds to b0, - y3 corresponds to b2, - y4 corresponds to b3, - y5 corresponds to b10, - y6 corresponds to b12, - y7 corresponds to b14, - y8 corresponds to b7, - y9 corresponds to b5, - y10 corresponds to b8, - y11 corresponds to b1, - y12 corresponds to b11, - y13 corresponds to b9, - y14 corresponds to b15, - y15 corresponds to b13. 14. Method according to claim 9 or 10, wherein said permutation is carried out on words of 16 bits and consists in generating a word B comprising in the order the bits b0 b1 b2 b3 b4 b5 b6 b7 b8 b9 b10 b11 b12 b13 b14 b15 , starting from a word Y comprising in the order the bits y0 y1 y2 y3 y4 y5 y6 y7 y8 y9 y10 y11 y12 y13 y14 y15, the bits y0 and b0 being respectively the most significant bits of the words Y and B and the bits y15 and b15 being respectively the least significant bits of words Y and B, where: - y0 corresponds to b0, - y1 corresponds to b12, - y2 corresponds to b4, - y3 corresponds to b6, - y4 corresponds to b8, - y5 corresponds to b14, - y6 corresponds to b2, - y7 corresponds to b10, - y8 corresponds to b1, - y9 corresponds to b13, - y10 corresponds to b5, - y11 corresponds to b7, - y12 corresponds to b9, - y13 corresponds to b15, - y14 corresponds to b3, - y15 corresponds to b11. 15. Method according to claim 9 or 10, wherein said permutation is carried out on words of 16 bits and consists in generating a word B comprising in the order the bits b0 b1 b2 b3 b4 b5 b6 b7 b8 b9 b10 b11 b12 b13 b14 b15 , starting from a word Y comprising in the order the bits y0 y1 y2 y3 y4 y5 y6 y7 y8 y9 y10 y11 y12 y13 y14 y15, the bits y0 and b0 being respectively the most significant bits of the words Y and B and the bits y15 and b15 being respectively the least significant bits of words Y and B, where: - y0 corresponds to b4, - y1 corresponds to b6, - y2 corresponds to b0, - y3 corresponds to b2, - y4 corresponds to b3, - y5 corresponds to b14, - y6 corresponds to b12, - y7 corresponds to b10, - y8 corresponds to b7, - y9 corresponds to b5, - y10 corresponds to b8, - y11 corresponds to b1, - y12 corresponds to b15, - y13 corresponds to b9, - y14 corresponds to b11, - y15 corresponds to b13. 16. A digital signal reception system comprising a demodulator of the QAM type, characterized in that it provides the method according to any one of claims 9 to 15.