KR101148492B1 - Apparatus of encoder for t-dmb system and method of encoding for t-dmb system - Google Patents

Abstract

An encoding apparatus of a T-DMB system, comprising: a first energy distributing scrambler for energy dispersing a payload input to a subchannel of the T-DMB system; A first convolutional encoder for convolutionally encoding the output of the first energy dispersive scrambler; A first interleaver for time interleaving the output of the first convolutional encoder; A limited reception scrambler for scrambling to provide the output of the first interleaver to a receiver having a broadcast reception right; A second energy dispersive scrambler for energy dissipating the output of the limited reception scrambler; A second convolutional encoder that convolutionally encodes an output of the second energy dispersive scrambler; A second interleaver for time interleaving the output of the second convolutional encoder; A main service multiplexer (MSM) for multiplexing the output of the second interleaver to generate a common interleaved frame (CIF); And a broadcast signal generation module configured to receive the CIF and generate an OFDM signal for digital broadcast transmission.

Description

Coding apparatus and coding method of TVD system {APPARATUS OF ENCODER FOR T-DMB SYSTEM AND METHOD OF ENCODING FOR T-DMB SYSTEM}

The following embodiments are related to an encoding apparatus and an encoding method of a T-DMB system.

Digital multimedia broadcasting (DMB) systems for high quality video services may be classified into T-DMB systems for terrestrial transmission and reception and S-DMB systems for transmission and reception of satellite signals.

The DMB system encodes video and audio sources, and objects and synchronizes each source stream. In addition, the DMB system removes the time correlation between adjacent byte units in the data stream, converts the output stream into a final digital broadcast signal through a digital audio broadcasting (DAB) transmitter, and outputs the final digital broadcast signal.

An embodiment of the present invention provides an encoding apparatus and method of a T-DMB system capable of improving encoding performance of a T-DMB system.

An embodiment of the present invention provides an encoding apparatus and method of a T-DMB system capable of recycling a conventional Viterbi decoder.

An encoding apparatus of a T-DMB system according to an embodiment of the present invention includes an encoding apparatus of a T-DMB system, the apparatus comprising: a first energy distribution scrambler configured to energy-distribute a payload input to a subchannel of the T-DMB system; A first convolutional encoder for convolutionally encoding the output of the first energy dispersive scrambler; A first interleaver for time interleaving the output of the first convolutional encoder; A limited reception scrambler for scrambling to provide the output of the first interleaver to a receiver having a broadcast reception right; A second energy dispersive scrambler for energy dissipating the output of the limited reception scrambler; A second convolutional encoder that convolutionally encodes an output of the second energy dispersive scrambler; A second interleaver for time interleaving the output of the second convolutional encoder; A main service multiplexer (MSM) for multiplexing the output of the second interleaver to generate a common interleaved frame (CIF); And a broadcast signal generation module that receives the CIF and generates an OFDM signal for digital broadcast transmission.

The apparatus may further include a signaling information generator configured to generate signaling information indicating the number of convolutional encodings for the payload input to the sub-channel of the T-DMB system.

The broadcast signal generation module may generate the OFDM signal using the CIF and the signaling information.

The signaling information generation unit may insert the signaling information into multiplex configuration information (MCI) indicating the configurations of services multiplexed by the MSM.

The signaling information generator may insert the signaling information into a payload input to a subchannel of the T-DMB system.

And an RS encoder for inserting a Reed Solomon (RS) code for error correction encoding into a payload input to a subchannel of the T-DMB system, wherein the first energy distributing scrambler includes the payload in which the RS code is inserted. The load can be energy dissipated.

The sub-channel of the T-DMB system may include at least one audio channel and at least one video channel.

In addition, the encoding method of the T-DMB system according to an embodiment of the present invention, the encoding method of the T-DMB system, the method comprising: performing a first energy distribution scrambling of the payload input to the sub-channel of the T-DMB system; First convolutional encoding the result of the first energy distribution scrambling; First interleaving the result of the first convolutional coding; Limited reception scrambling to provide a result of the first time interleaving to a receiver having a broadcast reception right; Second energy distribution scrambling of the result of the limited reception scrambling; Performing a second convolutional encoding on the result of the second energy distribution scrambling; Second time interleaving the result of the second convolutional coding; Generating a CIF by multiplexing the result of the second time interleaving; And receiving the CIF to generate an OFDM signal for digital broadcast transmission.

The method may further include generating signaling information indicating the number of convolutional encodings for the payload input to the sub-channel of the T-DMB system.

The generating of the OFDM signal may include generating the OFDM signal by using the CIF and the signaling information.

The generating of the signaling information may further include inserting the signaling information into multiplex configuration information (MCI) indicating configurations of services multiplexed by the MSM.

The generating of the signaling information may further include inserting the signaling information into a payload input to a subchannel of the T-DMB system.

And inserting an RS code for error correction encoding into a payload input to a sub-channel of the T-DMB system, wherein the first energy variance scrambling comprises energizing the payload into which the RS code is inserted. Can be distributed.

The sub-channel of the T-DMB system may include at least one audio channel and at least one video channel.

According to an embodiment of the present invention, encoding performance can be improved by performing energy distribution scrambling, interleaving, and convolutional coding once more upon input of payload for a subchannel of a T-DMB system. .

According to an embodiment of the present invention, the encoding apparatus of the T-DMB system performs selective decoding according to the signaling information by including signaling information indicating the number of convolutional encodings of the encoding apparatus when encoding the T-DMB system. can do.

1 is a diagram illustrating a T-DMB system including an encoding apparatus of a T-DMB system according to an embodiment of the present invention.
2 is a flowchart illustrating an encoding method of a T-DMB system according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited or limited by the embodiments. Also, like reference numerals in the drawings denote like elements.

1 is a diagram illustrating a T-DMB system including an encoding apparatus of a T-DMB system according to an embodiment of the present invention.

Referring to FIG. 1, an encoding apparatus of a T-DMB system according to an embodiment of the present invention may include a first energy distribution scrambler 101, a first convolutional encoder 103, a first interleaver 105, and a limited reception scrambler. 107, a second energy distribution scrambler 109, a second convolutional encoder 111, a second interleaver 113, an MSM 115, and a broadcast signal generation module 120.

In addition, the encoding apparatus of the T-DMB system according to an embodiment of the present invention may further include a signaling information generator 130 and an RS encoder 140.

The first energy dispersal scrambler 101 energy disperses a payload, which is data such as, for example, MPEG 2 or MPEG 4, which is input to a sub-channel of a T-DMB system.

The sub-channels of the T-DMB system may include at least one audio channel, at least one video channel, and a general data channel, and may include an MPEG (Motion Picture Experts Group) encoded audio data stream inputted through these sub-channels. Data Stream) or a generic data stream may be energy dissipated through the first energy distributing scrambler 101.

The first convolutional encoder 103 convolutionally encodes an output of the first energy distributing scrambler 101.

In addition, the first convolutional encoder 103 sets the output of the energy distribution scrambler 101 at different coding rates according to an Unequal Error Protection (UEP) or Equal Error Protection (EEP) profile. Can be encoded.

The first interleaver 105 receives the output of the first convolutional encoder 103 and time interleaves the respective logical frame sections.

The conditional access scrambler 107 scrambles the output of the first interleaver 105 so that it can be provided to the receiver having the right to receive the broadcast. Here, scrambling by the limited reception scrambler 107 may be selectively used as necessary.

The second energy dispersive scrambler 109 energy dissipates the output of the limited receiving scrambler 107 again. Here, the energy dispersion may use, for example, a distributed polynomial of the standard document (ETSI EN 300 401) and other distributed polynomials having the same function.

The second convolutional encoder 111 convolutionally encodes the output of the second energy dispersive scrambler 109. In general, in the case of convolution coding and Viterbi decoding, the coding performance is not as good as that of turbo coding. However, by performing the convolutional coding twice as in the embodiment of the present invention, the same effect as that of the turbo coding can be obtained. In addition, there is an advantage that the same effect as turbo coding can be obtained without major changes to the standard of the T-DMB system.

The second interleaver 113 time interleaves the output of the second convolutional encoder 111. Data of each subchannel time-interleaved in the second interleaver 113 may be multiplexed in the MSM 115 to form a CIF.

The MSM 115 multiplexes the output of the second interleaver 113 to generate a CIF.

The broadcast signal generation module 120 receives the CIF generated by the MSM 115 and generates an OFDM signal for digital broadcast transmission.

In addition, the broadcast signal generation module 120 may generate an OFDM signal using CIF and signaling information. In this case, the signaling information may be inserted into the multiplex configuration information (MCI) indicating the configurations of services multiplexed by the MSM 115 and input to the broadcast signal generation module 120.

The CIF and signaling information input to the broadcast signal generation module 120 may be input to the fast information channel (FIC) & main service channel (MSC) symbol generator 123 through the transmission frame multiplexer 121.

The FIC & MSC symbol generator 123 may generate the CIF and signaling information input to the broadcast signal generation module 120 as a frequency interleaved symbol.

The symbol generated by the FIC & MSC symbol generator 123 and the symbol generated by the sync channel symbol generator 125 may be input to the OFDM signal generator 127 and generated as an OFDM signal for digital broadcast transmission.

The OFDM signal generated by the OFDM signal generator 127 may be finally combined with the TII signal generated by the TII signal generator 129 and transmitted as a DAB (Digital Audio Broadcasting) transmission signal.

The signaling information generator 130 may generate signaling information indicating the number of convolutional encodings for the payload input to the subchannel of the T-DMB system.

In addition, the signaling information generation unit 130 may insert signaling information into multiplex configuration information (MCI) indicating the configurations of services multiplexed by the MSM 115.

In the encoding apparatus of the T-DMB system according to an embodiment of the present invention, the encoding apparatus of the T-DMB system includes signaling information indicating the number of convolutional encodings of the encoding apparatus when the T-DMB system is encoded. Accordingly, selective decoding may be performed.

That is, for example, the signaling information generation unit 130 inserts the signaling information into the multiplex configuration information (MCI) so that when the value of the multiple configuration information (MCI) is '0', the service for the audio data is '1'. In this case, the service for general data may be provided, and in case of '5', the service for data that has undergone two convolutional decoding may be provided.

In addition, the signaling information generation unit 130 may insert the signaling information into the payload input to the sub-channel of the T-DMB system to allow the decoding apparatus to selectively perform decoding during decoding.

In the T-DMB decoding apparatus according to an embodiment of the present invention, when convolutional decoding is required twice, such as when the multiplex configuration information (MCI) is '5', the signaling information inserted in the payload is 2 In case of indicating that the data requires convolutional decoding, the data can be decoded by repeating the time de-interleaving, the convolutional decoding, and the energy distribution de-scrambling in the reverse order of encoding.

Of course, if the signaling information indicates data that has undergone one convolutional decoding based on the signaling information, the T-DMB decoding apparatus may decode the data in the general order of time deinterleaving, convolutional decoding, and energy distribution de-scrambling. Can be.

The RS encoder 140 may insert an RS code for error correction encoding into a payload input to a subchannel of a T-DMB system.

When the RS code is inserted into the payload, the first energy distributing scrambler 101 may energy disperse the payload into which the RS code is inserted.

Here, a channel coding scheme having various error correction functions may be used in place of the RS code. For example, a low density parity check (LDPC) code, a bose-chaudhuri-hocquenghen (BCH) code, and a variable channel coding rate may be used. This may be a Rate Compatible Punctured Code (RCPC).

2 is a flowchart illustrating an encoding method of a T-DMB system according to an embodiment of the present invention.

Referring to FIG. 2, in the encoding method of the T-DMB system according to an embodiment of the present invention, the encoding apparatus of the T-DMB system firstly scrambles the payload input to the sub-channel of the T-DMB system ( 201).

Further, the encoding method of the T-DMB system according to an embodiment of the present invention may further include inserting an RS code for error correction encoding into the payload input to the sub-channel of the T-DMB system before step 301. Can be.

The encoding apparatus of the T-DMB system may energy disperse the payload into which the RS code is inserted when an RS code for error correction encoding is inserted into the payload.

Here, the sub-channel of the T-DMB system may include at least one audio channel and at least one video channel.

The encoding apparatus of the T-DMB system first convolutionally encodes the result of the first energy distribution scrambling (203), and first temporally interleaves (205) the result of the first convolutional encoding.

The encoding apparatus of the T-DMB system scrambles limited reception in order to provide limited results of the first time interleaving to a receiver having a right broadcast reception right (207).

Here, the receiver having the right to receive a broadcast is a signal received by a method of receiving a control code or an identification code provided according to, for example, a member registration for listening to the broadcast, or paying a fee in advance with respect to the received signal for T-DMB. Refers to recipients who have a legitimate right to receive and can be applied as needed, not always applicable.

The encoding apparatus of the T-DMB system performs second energy distribution scrambling on the result of the limited reception scrambling (209), performs second convolutional coding (211), and interleaves the second time (213).

The MSM multiplexes the result of the second time interleaving to generate CIF (215).

The encoding apparatus of the T-DMB system receives the generated CIF and generates an OFDM signal for digital broadcast transmission (217).

The encoding method of the T-DMB system according to an embodiment of the present invention may further include generating signaling information indicating the number of convolutional encodings for the payload input to the subchannel of the T-DMB system. .

The signaling information is for indicating information about the decoding process performed by the decoding apparatus according to whether the encoding apparatus of the T-DMB system performs the convolutional encoding of the payload once or twice.

The encoding apparatus of the T-DMB system may generate an OFDM signal using the CIF and the signaling information at 217.

In the generating of the signaling information, the encoding apparatus of the T-DMB system may further include inserting signaling information into multiplex configuration information (MCI) indicating configurations of services multiplexed by the MSM.

In addition, the generating of the signaling information may include inserting the signaling information into the payload input to the sub-channel of the T-DMB system.

That is, the signaling information may be inserted into a multiplex configuration information (MCI) or a payload input to a subchannel from a service input terminal and provided to a decoding apparatus of a T-DMB system.

Although omitted below, the above descriptions of the encoding apparatus of the T-DMB system described with reference to FIG. 1 may be mutually applied to the encoding method of the T-DMB system described with reference to FIG. 2.

The above-described methods may be embodied in the form of program instructions that can be executed by various computer means and recorded on a computer-readable medium. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine code generated by a compiler, but also high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above embodiments, and various modifications and variations will be made to those skilled in the art to which the present invention pertains. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the claims below, but also by those equivalent to the claims.

101: first energy dispersive scrambler
103: First Convolutional Encoder
105: first interleaver
107: limited reception scrambler
109: second energy dispersive scrambler
111: Second Convolution Encoder
113: second interleaver
115: MSM
120: broadcast signal generation module
130: signaling information generation unit

Claims (15)

In the encoding apparatus of the T-DMB system,
A first energy distributing scrambler for energy dispersing a payload input to a subchannel of the T-DMB system;
A first convolutional encoder for convolutionally encoding the output of the first energy dispersive scrambler;
A first interleaver for time interleaving the output of the first convolutional encoder;
A limited reception scrambler for scrambling to provide the output of the first interleaver to a receiver having a broadcast reception right;
A second energy dispersive scrambler for energy dissipating the output of the limited reception scrambler;
A second convolutional encoder that convolutionally encodes an output of the second energy dispersive scrambler;
A second interleaver for time interleaving the output of the second convolutional encoder;
A main service multiplexer (MSM) for multiplexing the output of the second interleaver to generate a common interleaved frame (CIF); And
A broadcast signal generation module that receives the CIF and generates an OFDM signal for digital broadcast transmission
Encoding apparatus of the T-DMB system comprising a. The method of claim 1,
Signaling information generation unit for generating signaling information indicating the number of convolutional encoding for the payload input to the sub-channel of the T-DMB system
Encoding apparatus of the T-DMB system further comprising. The method of claim 2,
The broadcast signal generation module
The encoding apparatus of the T-DMB system for generating the OFDM signal using the CIF and the signaling information. The method of claim 2,
The signaling information generator
And encoding the signaling information into multiplex configuration information (MCI) indicating the configurations of services multiplexed by the MSM. The method of claim 2,
The signaling information generator
The encoding apparatus of the T-DMB system inserts the signaling information into the payload input to the sub-channel of the T-DMB system. The method of claim 1,
RS encoder for inserting a Reed Solomon (RS) code for error correction encoding into the payload input to the sub-channel of the T-DMB system
Further comprising:
The first energy dispersive scrambler
The coding apparatus of the T-DMB system for energy distribution of the payload in which the RS code is inserted. The method of claim 1,
The sub-channel of the T-DMB system is
An encoding apparatus of a T-DMB system including at least one audio channel and at least one video channel. In the coding method of a T-DMB system,
A first energy distribution scrambling of the payload input to the sub-channel of the T-DMB system;
First convolutional encoding the result of the first energy distribution scrambling;
First interleaving the result of the first convolutional coding;
Limited reception scrambling to provide a result of the first time interleaving to a receiver having a broadcast reception right;
Second energy distribution scrambling of the result of the limited reception scrambling;
Performing a second convolutional encoding on the result of the second energy distribution scrambling;
Second time interleaving the result of the second convolutional coding;
Generating a common interleaved frame (CIF) by multiplexing the result of the second time interleaving by a main service multiplexer (MSM); And
Receiving the CIF and generating an OFDM signal for digital broadcast transmission
Encoding method of a T-DMB system comprising a. The method of claim 8,
Generating signaling information indicating the number of convolutional encodings for the payload input to the sub-channel of the T-DMB system;
Encoding method of the T-DMB system further comprising. 10. The method of claim 9,
Generating the OFDM signal
And generating the OFDM signal by using the CIF and the signaling information. 10. The method of claim 9,
Generating the signaling information
Inserting the signaling information into multiplex configuration information (MCI) indicating configurations of services multiplexed by the MSM
Encoding method of the T-DMB system further comprising. 10. The method of claim 9,
Generating the signaling information
Inserting the signaling information into a payload input to a subchannel of the T-DMB system;
Encoding method of the T-DMB system further comprising. The method of claim 8,
Inserting an RS (Reed Solomon) code for error correction encoding into a payload input to a sub-channel of the T-DMB system;
Further comprising:
The step of scrambling the first energy distribution is
Encoding method of the T-DMB system for energy distribution of the payload inserted with the RS code. The method of claim 8,
The sub-channel of the T-DMB system is
A coding method of a T-DMB system including at least one audio channel and at least one video channel. A computer-readable recording medium having recorded thereon a program for performing the method of claim 8.

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