CA2635234C - Digital broadcasting transmission system and method thereof - Google Patents

Abstract

A digital broadcasting transmission system and method thereof. The digital broadcasting transmission system, comprises an RS encoder to encode a dual transport stream (TS) which includes a normal stream and a plurality of turbo streams multiplexed together, an interleaver to interleave the encoded dual TS, a turbo processor to detect the turbo streams from the interleaved dual TS and to encode the detected turbo stream, and a trellis encoder to pseudo2 (P-2) vestigial sideband (VSB) code the turbo-processed dual TS, and, then, to perform trellis encoding, and a main multiplexer (MUX) to multiplex the trellis-encoded dual TS by adding a field synchronous signal and a segment synchronous signal thereto.

Description

Description DIGITAL BROADCASTING TRANSMISSION SYSTEM AND
METHOD THEREOF
Technical Field [11 An aspect of the present invention relates to a digital broadcasting transmission system and a method thereof. More particularly, an aspect of the present invention relates to a digital broadcasting transmission system enabling an improved receptivity, by using a variety of methods to code a turbo stream, and a method thereof.
Background Art

[2] According to the Advanced Television System Committee (ATSC) Digital Vestigial Side Band (VSB) technologies, the U.S. oriented terrestrial digital broadcasting system uses a single carrier and field sync signal of 312-segment unit. This system has poor receptivity particularly in the bad channel such as Doppler fading channel.
[31 FIG. 1 is a block diagram of a conventional ATSC VSB broadcasting transmission apparatus, and FIG. 2 shows the frame structure of data used in the system of FIG. 1.
[4] More specifically, FIG. 1 shows an EVSB system, which makes and sends out a dual transport stream (TS) by adding robust data to the normal data of an existing ATSC VSB system.
[51 Referring to FIG. 1, the transmission of the conventional digital broadcasting transmission system is explained below.
[6] A normal stream, a place holder packet and a turbo stream are fed to a TS
constructor 11 in which a dual TS is constructed.
[71 The dual TS is randomized at the randomizer 13, a parity bit is appended to the transmitted stream for en-or correction at a Reed-Solomon (RS) encoder 15, and a packet is re-constructed at a packet formatter 17. Additionally, the re-constructed packet is interleaved at an interleaver 19, and the interleaved data is trellis-encoded at a trellis encoder 21. The trellis encoder 21 generates a compatible parity bit through an interaction with a compatible parity generator 23.
[8] After the data is error-corrected at the trellis encoder 21, the error-corrected data is multiplexed at a multiplexer (MUX) 27 which inserts field sync and segment sync signals in the data. Then the processes of pilot signal insertion, VSB
conversion and up-conversion to RF channel signal levels, are performed and the data is transmitted through the channel. The above operations may be controlled by the control signal from a controller 25.
[91 As shown in FIG. 2, a data frame that is applied to the digital broadcasting transmission apparatus of FIG. 1 has consecutive packets MO through M51, and is formatted at a packet formatter 17 and outputted. As shown, the turbo stream and the normal stream are arranged at the rate of 1:3.
Disclosure of Invention Technical Problem [101 A problem of the VSB system is performance degradation due to dynamic multipath interference and a weak signal. However, notwithstanding the fact that they use a dual TS which includes normal stream added with turbo stream, the conventional digital broadcasting transmission systems, as the ones shown in FIGS. 1 and 2, could hardly improve bad receptivity by the transmission of a normal stream in the multipath channel.
[11] Additionally, at relatively high power levels, that is, as 4th level power used among the existing 8 levels of power, average power consumption of the stream increases. If many turbo streams are used, quality of normal stream will relatively deteriorate.
Therefore, adding a turbo stream to the normal stream has to be limited.
Technical Solution [121 An Aspect of the present invention is to provide a digital broadcasting transmission system which is capable of adding as many turbo streams as is necessary, without being limited to a certain rate, by applying P2-VSB coding to the turbo stream.
[131 In accordance with the above aspect of the present invention, the digital broadcasting transmission system, comprises an RS encoder to encode a dual transport stream (TS) which includes a normal stream and a plurality of turbo streams multiplexed together, an interleaver to interleave the encoded dual TS, a turbo processor to detect the turbo streams from the interleaved dual TS and to encode the detected turbo stream, and a trellis encoder to pseudo2 (P-2) vestigial sideband (VSB) code the turbo-processed dual TS, and, then, to perform trellis encoding, and a main multiplexer (IVIUX) to multiplex the trellis-encoded dual TS by adding a field synchronous signal and a segment synchronous signal thereto.
[14] In accordance with another aspect of the present invention, a digital broadcasting transmission method, comprises encoding a dual transport stream (TS) which includes a normal stream and a plurality of turbo streams that are multiplexed together; in-terleaving the encoded dual TS, detecting the turbo streams from the interleaved dual TS and encoding the detected turbo stream, and pseudo2 (P-2) VSB coding the turbo-processed dual TS, and then performing trellis encoding, and multiplexing the trellis-encoded dual TS by adding a field synchronous signal and a segment synchronous signal thereto.

2a [14a] According to another aspect of the present invention, there is provided a digital broadcasting transmission apparatus, comprising: a Reed Solomon (RS) encoder to RS-encode an first data without RS-encoding a second data; an encoder to convolutional-encode the RS-encoded first data; a packet formatter to reconstruct the convolutional-encoded first data; a Transport Stream (TS) multiplexer to multiplex the reconstructed first data with the second data; a trellis encoder to perform trellis encoding a stream which the first data and the second data are multiplexed; and, a compatible parity generator to generate a compatible parity bit based the trellis encoded stream.
[14b] According to yet another aspect of the present invention, there is provided a stream processing method of a digital broadcasting transmission apparatus, the method comprising: Reed Solomon (RS)-encoding an first data without RS-encoding a, second data;
convolutional-encoding the RS-encoded first data; reconstructing the convolutional-encoded first data; multiplexing the reconstructed first data with the second data; a trellis encoder to perform trellis encoding a stream which the first data and the second data are multiplexed;
and, a compatible parity generator to generate a compatible parity bit based the trellis encoded stream.
[15] Additional and/or other aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description,

3 or may be learned by practice of the invention.
Advantageous Effects [16] As described above, according to aspects of the present invention, a broadcasting service can be performed using a dual transmission stream including a turbo stream and a normal stream.
Brief Description of the Drawings [17] These and/or other aspects and advantages of the invention will become apparent and more readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:
[18] FIG. 1 is a block diagram of a conventional ATSC digital broadcasting transmission system;
[19] FIG. 2 illustrates the frame structure of data used in the system of FIG. 1;
[20] FIG. 3 is a block diagram of a digital broadcasting transmission system according to an exemplary embodiment of the present invention;
[21] FIG. 4 is a block diagram of the TS constructor of FIG. 3;
[22] FIGS. 5 through 7 are views illustrating a packet output from the TS
constructor;
[23] FIG. 8 is a block diagram of the turbo processor of FIG. 3;
[24] FIG. 9 illustrate inner structure of a trellis encoder of FIG. 3;
[25] FIG. 10 illustrates a first encoder of FIG. 9;
[26] FIG. 11 is a block diagram of a digital broadcasting transmission system according to another exemplary embodiment of the present invention;
[27] FIGS. 12 and 13 show transmission stream which includes SRS data;
[28] FIG. 14 is a block diagram of a SRS inserter of FIG. 11;
[29] FIG. 15 illustrates a trellis encoder of FIG. 11;
[30] FIG. 16 illustrates a first encoder of FIG. 15;
[31] FIG. 17 is a block diagram of a digital broadcasting reception system applied to the present invention;
[32] FIGS. 18 and 19 are diagrams showing the operation of viterbi decoder of FIG. 17;
[33] FIG. 20 is a block diagram of a turbo decoder of FIG. 17;
[34] FIG. 21 is a flowchart provided to explain a method of digital broadcasting transmission according to an exemplary embodiment of the present invention.
Best Mode for Carrying Out the Invention [35] Reference will now be made in detail to the present embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. The embodiments are described below in order to explain the present invention by referring to the figures.
[36] FIG. 3 is a block diagram of a digital broadcasting transmission system according to

4 an exemplary embodiment of the present invention. As shown in FIG. 3, a digital broadcasting system according to an exemplary embodiment of the present invention includes a TS constructor 110, a randomizer 120, an RS encoder 130, a parity formatter 140, an interleaver 150, a turbo processor 160, a trellis encoder 170, a compatible parity generator 180, a controller 190, a main multiplexer (MUX) 200, a pilot inserter 310, a vestigial sideband (VSB) modulator 320, and a radio frequency (RF) converter 330.
[37] The TS constructor 110 receives an input of a normal stream and a plurality of turbo streams, and processes the turbo streams from among the received data. The TS
constructor 110 then multiplexes the normal stream and the turbo stream to construct a dual transport stream (TS). The TS constructor 110 will be explained in greater detail below with reference to FIGS. 4, 5, 6 and 7.
[38] The randomizer 120 randomizes the dual TS received from the TS
constructor 110.
By the operation of the randomizer 201, a utilization of channel space is increased.
[39] The RS encoder 130 encodes the dual TS which is randomized at the randomizer 120. The RS encoder 130 may be implemented as a concatenated coder which adds a parity bit to the transmission stream in order to correct a channel-generated error during the transmission.
[40] The parity formatter 140 determines the position of the parity bit in the RS encoded dual TS. Therefore, the parity formatter 140 does not operate with respect to the packet having normal data only, but, rather, determines the position of the packet having turbo data, in order to prevent the parity bit from proceeding to the turbo data position after the interleaving.
[41] With reference to an example of the packet as shown in FIG. 6, the parity formatter 140 changes the parity bit to predetermined data. The parity formatter 140 calculates the position of the parity bit by the following:
[42] (Mathematical expression) [43] m=(52*n+k)%207 [44] where, m refers to the position of a parity bit before interleaving, n is the position of parity bit after interleaving (n=0,1,...,206), and k is the result of calculating the order of packets in a field by module 52 (k=0,1,...,51).
[45] The above mathematical expression is used to calculate the value of m from 187 to 206, and does not take the result if the parity bit is located in the PID, AF
header and normal data. The position of the parity bit is determined by iteratively applying the above mathematical expression while changing the starting position one by one.
[46] Taking the example of the 10th segment which includes 128 byte turbo data, and 54 byte normal data, the parity bit overlaps the PD, AF header and normal data by bytes. In this case, the position of the parity bit is calculated by applying the above

5 mathematical expression 1 to 176 to 206 and a 20 byte parity bit position is determined.
[47] Accordingly, the parity formatter 140 first inserts predetermined data to the position of the parity bit excluding the MD, AF header and normal data, and then inserts turbo data in the remaining parts, to construct a new packet structure.
[48] The interleaver 150 interleaves the dual TS. The 'interleaving' changes the position of the data in frame but does not change the data, per se.
[49] The turbo processor 150 separates the normal stream and the turbo stream from the dual TS which is interleaved at the interleaver 150, and encodes the separated turbo stream to strengthen the turbo stream. The turbo processor 160 will be explained in greater detail below with reference to FIGS. 9 and 10.
[50] The trellis encoder 170 pseudo 2-VSB (P-2 VSB) codes the turbo-processed dual TS, and performs trellis encoding. The trellis encoder 170 will be explained in greater detail below with reference to FIGS. 11 and 13.
[51] The compatible parity generator 180 generates a compatible parity bit for the com-patibility with a receiver device, through an interaction with the trellis encoder 170.
The compatible parity generator 180 may generate a compatible parity bit based on the dual TS packet, which is appended with the parity at the RS encoder 130, and the dual TS, which is encoded at the trellis encoder 170.
[52] The controller 190 controls the normal stream and the turbo stream at the TS
constructor 110, the parity formatter 140, the turbo processor 160 and the trellis encoder 170 according to a predetermined control signal.
[53] The main MUX 200 appends field sync and segment sync signals to the dual TS
provided from the trellis encoder 170, to multiplex the streams.
[54] According to one aspect of the present invention, the turbo stream processed at the turbo processor 160, the turbo stream processed at the turbo processor 160 and P2-VSB coded at the trellis encoder 170, the turbo stream processed at the turbo processor 160, and the turbo stream P2-VSB coded and trellis encoded at the trellis encoder 170, and the normal stream may all be multiplexed.
[55] The pilot inserter 310 appends a pilot signal to the dual TS which is appended with the field sync and segment sync signals at the main MUX 200. The pilot signal appears as a relatively small DC phase voltage is applied to an 8-VSB base band immediately before the modulation, so that a relatively small carrier appears in the zero frequency point of the modulated spectrum. The pilot signal synchronizes the signal to the RF
PLL circuit of the receiver device, regardless of the transmission signal.
[56] The VSB modulator 320 pulse-shapes the transmission stream which is appended with the pilot signal at the pilot inserter 310, and loads the transmission stream to the intermediate frequency carrier so as to perform VSB modulation which modulates

6 amplitude.
[57] The RF converter 330 RF-converts the VSB-modulated transmission stream at the VSB modulator 320, and amplifies and transmits the transmission stream to a pre-determined band through an allotted channel.
[58] FIG. 4 is a block diagram of the TS constructor of FIG. 3. As shown in FIG. 4, the TS constructor 110 applied to the digital broadcasting transmission system according to one exemplary embodiment of the present invention includes an input MUX
112, an RS encoder 114, a packet formatter 116 and a TS MUX 118. The input MUX 112 multiplexes a plurality of turbo streams which are inputted to the TS
constructor 110.
One of the plurality of turbo streams goes through the turbo coding, another goes through the P2-VSB coding, and another goes through the turbo coding and then P2-VSB coding. The RS encoder 114 RS-encodes the turbo stream, which is multiplexed at the input MUX 112. The packet formatter 116 re-constructs the packet of the turbo stream which is RS-encoded at the RS encoder 114. The TS MUX 118 multiplexes the turbo stream whose packet is reconstructed at the packet formatter 116, with the normal stream, and, thus, constructs a dual TS.
[59] FIGS. 5 through 7 are views to show an exemplary packet being outputted from the TS constructor 110.
[60] Generally, a packet applied to the digital broadcasting includes a 1-byte synchronous signal, a 3-byte header and a 184-byte payload. The header of the packet includes a packet identifier (PID). The data in the payload is categorized into either a normal stream and/or at least one turbo stream according to the type of data included in the payload.
[61] As shown in FIG. 5, the normal stream (a) is inputted to the TS
constructor 100, and the normal data (b) is included in the payload part. Additionally, there is an adaptation field showing the normal data mixed with the turbo data. The adaptation field includes 2-byte AF header and (N)-byte turbo data+null data space. FIG. 6 shows the two packets having a turbo stream and a normal stream, respectively, which may be combined with each other at the TS constructor at the rate of 1:3 or 2:2. FIG.

7 shows an exemplary structure of the packet corresponding to one field which is constructed in the form as shown in FIG. 6 at the TS constructor 110, and which is inputted to the randomizer 120. The normal data and the turbo data are combined in the 3:1 rate.
[62] FIG. 8 is a block diagram of the turbo processor of FIG. 3. As shown in FIG. 8, the turbo processor 160 applied to the digital broadcasting transmission system of the present invention includes a turbo extractor 162, an outer encoder 164, an outer in-terleaver 514 and a processor MUX 168. The turbo extractor 162 extracts a turbo stream from the dual TS which is inputted to the turbo processor 160. The outer encoder 164 performs convolution encoding with respect to the turbo stream which is extracted at the turbo extractor 162. The outer interleaver 514 interleaves the turbo stream which is convolution-encoded at the outer encoder 164. The processor MUX
168 multiplexes the turbo stream and the normal stream interleaved at the outer in-terleaver 514, and outputs the resultant stream.
[63] FIG. 9 shows the inner structure of the trellis encoder of FIG. 3, and FIG. 10 shows the first encoder. As shown in FIG. 9, the trellis encoder 170 includes a first encoder 172 for P-2 VSB coding, and a second encoder 174 for general trellis encoding.
[64] Referring to FIG. 10, as shown in FIG. 10, the first encoder 172 includes a first MUX 172a, a second MUX 172b, a third MUX 172c, a first adder 172d and a control signal generator (not shown). The first MUX 172a selectively outputs one among the first and the second inputs X and X. The first input X is also inputted to the second MUX 172b. The first adder 172d adds the output from the first MUX 172a and the input from a predetermined register Do, and outputs the resultant value. The register Do may be the first register of the second encoder. The second MUX 172b selectively outputs one among the first input Xi and the output from the first adder 172d.
The output X2' ofthe second MUX 172 is input to the second encoder 174. The third MUX
172c selectively outputs either the second input X2 or the output of the first MUX 172.
The output Xi' of the third MUX 172c is input to the second encoder.
[65] The control signal generator (not shown) provides a control signal to select one among the plurality of inputs from the first through third MUXes 172a through 172c.
[66] Accordingly, the first encoder 172 removes a pre-coding effect so that two outputs of the trellis encoding, with respect to the data for P-2 VSB coding among the plurality of turbo streams inputted to the TS constructor, may have the same value.
[67] The second encoding is processed using the outputs from the first encoder 172, as the one shown in FIG. 10. Referring to FIG. 9, the second encoder 174 includes first through third registers Do, Di, D2, the second adder 174a and the third adder 174b.
[68] The first through third registers D, D, D have predetermined bit-values.
o1 2 [69] The second adder 174a adds one X' among the outputs from the first encoder, with the stored value of the first register Do' and outputs the resultant data and stores the output Z2 in the first register D.
[70] The third adder 174b adds another one X' among the outputs from the first encoder, with the stored value of the second register D, and outputs the resultant data and stores the output Zo in the first register D.
[71] According to one exemplary embodiment of the present invention, as the data go through the processes of turbo coding at the turbo processor 160 and the P-2 VSB
coding at the first encoder 172, new data, which is different from the conventional packet data, is formed. Accordingly, incorrect RS decoding is possible at the receiver device. In order to prevent incorrect RS decoding, the compatible parity generator 180

8 generates a compatible parity bit to be inserted in the parity bit location of the data from the first encoder 172.
[72] FIG. 11 is a block diagram of a digital broadcasting transmission system according to another exemplary embodiment of the present invention. FIGS. 12 through 13 show the transmission stream including supplementary reference signal (SRS) data therein.
[73] As shown in FIG. 11, the digital broadcasting transmission system according to another exemplary embodiment of the present invention includes a TS
constructor 110, a randomizer 120, an SRS inserter 125, an RS encoder 130, a parity formatter 140, an interleaver 150, a turbo processor 160, a trellis encoder 170, a compatible parity generator 180, a controller 190, a main MUX 200, a pilot inserter 310, a VSB
modulator 320 and an RF converter 330.
[74] The digital broadcasting transmission system according to this exemplary embodiment of the present invention has a similar structure as the one shown in FIG.
3. Accordingly, the like elements are given the same reference numerals and only the different parts of the embodiment will be explained below.
[75] From the packet including adaptation field as shown in FIG. 5, a dual TS, which includes a stuffing region in the adaptation field, is inputted to the randomizer 120.
[76] The SRS inserter 125 inserts a supplementary reference signal (SRS) to the stuffing region of the dual TS which is randomized at the randomizer 120. According to the AF
header and the stuff bytes inserted in the dual TS, a loss of payload due to the SRS and a mixing rate may be determined. This will be explained in greater below with reference to the SRS inserter 125 as shown in FIG. 14.
[77] FIGS. 12 and 13 show the packet which includes SRS data inserted by the SRS
inserter 125. As shown, both the normal stream and the robust stream include S-byte of SRS data.
[78] Explanation of the remaining elements will be omitted for the sake of brevity, as it has already been explained above with reference to FIG. 3.
[79] FIG. 14 is a block diagram of the SRS inserter of FIG. 11. As shown in FIG. 14, the SRS inserter 125 includes an SRS pattern memory 125a, and an SRS MUX 125b. The SRS pattern memory 125a stores an SRS pattern for insertion in the stuffing region.
The SRS pattern is made compatible with the receiver device in advance, and can be used in the equalizer of the receiver device. The SRS MUX 125b adds the SRS
pattern stored in the SRS pattern memory 125a, to the normal stream and the turbo stream, to perform multiplexing.
[80] FIG. 15 shows the trellis encoder of FIG. 11, and FIG. 16 shows the first encoder of FIG. 15. As shown in FIG. 15, the trellis encoder 170 according to one exemplary embodiment of the present invention includes a first encoder 172 and a second encoder 174. The second encoder 174 includes first through third registers Do, Di, D2, a second

9 adder 174a, and a third adder 174b, in the identical structure as the second encoder as shown in FIG. 9. The first encoder 172 of FIG. 16 includes first through third MUXes 172a through 172c, and the first adder 172b, in the same structure as the first encoder 172 as shown in FIG. 10.
[81] A difference of this embodiment from other embodiments of the present invention is in the P-2 VSB coding of the first encoder 172, which is performed before the trellis encoding of the second encoder 174. The SRS initialization signal is inputted to the second and the third MUXes 172b, 172c. The SRS initialization signal initializes the first through third registers D, D, D of the second encoder 174, that is, D =D
=D =O.

[82] FIG. 17 is a block diagram of a digital broadcasting reception system applied to the present invention, and FIGS. 18 and 19 are diagrams showing the viterbi decoder in use. As shown in FIG. 17, the digital broadcasting reception system includes a de-modulator 120, an equalizer 420, a viterbi decoder 430, a receiver MUX 440, a first deinterleaver 450, an RS decoder 460, a first derandomizer 470, a first de-MUX
480, a turbo decoder 510, a second deinterleaver 150, a parity eraser 530, a second de-randomizer 540, and a second de-MUX 550.
[83] The demodulator 410 receives dual TS which is transmitted from the digital broadcasting transmission system as shown in FIG. 3 or FIG. 11, detects syn-chronization according to the synchronous signal added to the baseband signal, and performs demodulation.
[84] The equalizer 420 equalizes the dual TS which is demodulated at the demodulator 410. Accordingly, the equalizer 420 compensates for channel distortion due to multipath of the channel, and, thus, removes interferences of the received symbols.
[85] The viterbi decoder 430 corrects errors of the normal stream of the dual TS, decodes the en-or-corrected symbol, and, thus, outputs a symbol packet. The viterbi decoder 430 decodes the normal data using the diagram as shown in FIG. 18, while decoding P-2 VSB-coded data using the diagram as shown in FIG. 19.
[86] The receiver MUX 440 multiplexes the normal stream which is error-corrected at the viterbi decoder 430, and the turbo stream which is decoded at the turbo decoder 510.
[87] The first deinterleaver 450 deinterleaves the normal stream which is viterbi-decoded at the viterbi decoder 430.
[88] The RS decoder 460 RS-decodes the normal stream which is deinterleaved at the first deinterleaver 450.
[89] The first derandomizer 470 derandomizes the normal stream which is RS-decoded at the RS decoder 460, and outputs the resultant stream.
[90] The turbo decoder 510 decodes the turbo stream of the dual TS which is equalized at the equalizer 420. The turbo decoder 510 will be explained in greater detail below

10 with reference to FIG. 20.
[91] The second deinterleaver 150 deinterleaves the turbo stream which is decoded at the turbo decoder 510.
[92] The parity eraser 530 removes a parity bit, which is appended to the turbo stream deinterleaved at the second deinterleaver 150.
[93] The second derandomizer 540 derandomizes the turbo stream from which parity is removed at the parity eraser 530.
[94] The second de-MUX 550 demultiplexes the turbo stream which is derandomized at the second derandomizer 540.
[95] FIG. 20 is a block diagram of turbo decoder of FIG. 17. As shown in FIG. 20, the turbo decoder 510 includes a TCM map decoder 511, an outer deinterleaver 512, an outer map decoder 513, an outer interleaver 514, a frame formatter 515, and a symbol deinterleaver 516. The TCM map decoder 511 trellis-decodes the turbo stream.
The outer deinterleaver 512 deinterleaves the turbo stream which is trellis-decoded at the TCM map decoder 511. The outer map decoder 513 convolution-decodes the turbo stream which is deinterleaved at the outer deinterleaver 512. The outer interleaver 514 interleaves the turbo stream which is convolution-decoded at the outer map decoder [96] The frame formatter 515 adds the decoding data of the outer map decoder 513 to a location of the frame having the normal stream and the turbo stream mixed therein, corresponding to the location of the turbo stream.
[97] When information exchange is completed between the outer deinterleaver 512 and the outer interleaver 514 of the TCM map decoder 511 and the outer map decoder 513, the decoding data of the TCM map decoder 511 is outputted to use in the reception of normal stream, while the decoding data of the outer map decoder 513 is provided to the frame formatter 515.
[98] FIG. 21 is a flowchart provided to explain a method of digital broadcasting transmission according to an exemplary embodiment of the present invention.
[99] Hereinbelow, the digital broadcasting reception method according to the exemplary embodiment of the present invention will be explained with reference to FIGS.

through 21.
[100] The TS constructor 110 receives an input of a normal stream and a plurality of turbo streams, and performs RS-encoding and packet formatting with respect to the turbo streams. The TS constructor 110 then multiplexes the processed turbo streams and the normal stream, to construct a dual transport stream (TS) (op 600).
[101] The dual TS constructed at the TS constructor 110 is randomized at the randomizer 120 (op 610), RS-encoded at the RS encoder 130 (op 620), determined with the location of parity at the parity formatter 140 and formatted (op 630), and interleaved at =

11 the interleaver 150 (op 640).
[102] The interleaved dual TS is separated into the normal stream and the turbo streams at the turbo processor 160, and the turbo streams are turbo-coded (op 650).
[103] After the turbo coding, the trellis encoder 170 performs P-2 VSB
coding with the first encoder 172, and trellis encoding with the second encoder 174. At this time, through the interaction of the trellis encoder 170 and the compatible parity generator.
180, a compatible parity may be generated (op 660 to op 670).
[104] Accordingly, the turbo-processed turbo stream, the turbo stream which is turbo-processed, P-2 VSB-coded at the trellis encoder 170, and the turbo stream which is =
turbo processed, P-2 VSB coded and trellis-encoded at the trellis encoder 170, are formed, and the three types of turbo streams are multiplexed with the normal stream at the main MUX 200 and constructed into a new dual TS (op 690).
[105] After the dual TS constructed at the main MUX 200 goes through the process in which a pilot signal is inserted by the pilot inserter 310, and the processes of VSB
modulation at the VSB modulator 320, and RF conversion at the RF converter 330, the dual TS is transmitted through the predetermined channel (op 692).
[106] As is described above, the dual TS transmitted from the digital broadcasting transmission system is received at the digital broadcasting reception system, and goes through the processes such as modulation, equalization, viterbi decoding, dein-terleaving, RS decoding, derandomization and de-MUXing, and is thus recovered to the normal TS packet, the P-2 VSB TS packet, and the turbo TS packet.
[107] As is described above, the digital broadcasting transmission system and method thereof receives a normal stream and a plurality of turbo streams, applies a variety of coding methods, and, therefore, is able to add turbo streams without being limited to a.
certain mixing rate. Additionally, data reception at the poor channel environment is also improved.
[108] Although a few embodiments of the present invention have been shown and described, it would be appreciated by those skilled in the art that changes may be made in these embodiments without departing from the principles of the invention, the scope of which is defined in the claims and their equivalents.
[109]
[110]
Industrial Applicability [111] The present invention relate to DIGITAL BROADCASTING TRANSMISSION
SYSTEM AND METHOD THEREOF.
[112]
[113]

Claims (6)

CLAIMS:

1. A digital broadcasting transmission apparatus, comprising:
a Reed Solomon (RS) encoder to RS-encode an first data without RS-encoding a second data;
an encoder to convolutional-encode the RS-encoded first data;
a packet formatter to reconstruct the convolutional-encoded first data;
a Transport Stream (TS) multiplexer to multiplex the reconstructed first data with the second data;
a trellis encoder to perform trellis encoding a stream which the first data and the second data are multiplexed; and, a compatible parity generator to generate a compatible parity bit based the trellis encoded stream.

2. The digital broadcasting transmission apparatus of claim 1, further comprising an input multiplexer to multiplex the first data and provide the multiplexed first data to the RS
encoder.

3. The digital broadcasting transmission apparatus of claim 1, wherein the TS
multiplexer multiplexes a packet of the first data and a packet of the second data according to a predetermined ratio.

4. A stream processing method of a digital broadcasting transmission apparatus, the method comprising:
Reed Solomon (RS)-encoding an first data without RS-encoding a second data;
convolutional-encoding the RS-encoded first data;
reconstructing the convolutional-encoded first data;

multiplexing the reconstructed first data with the second data;
a trellis encoder to perform trellis encoding a stream which the first data and the second data are multiplexed; and, a compatible parity generator to generate a compatible parity bit based the trellis encoded stream.

5. The stream processing method of claim 4, further comprising multiplexing the first data and providing the multiplexed first data to an RS encoder.

6. The stream processing method of claim 4, wherein the multiplexing multiplexes a packet of the first data and a packet of the second data according to a predetermined ratio.