KR20060072574A - Digital multimedia broadcasting transmitter and receiver - Google Patents

Abstract

The present invention relates to a digital multimedia broadcasting transmitter and receiver.

The present invention provides a digital audio broadcast signal encoder for encoding a digital audio broadcast signal, and an FEC for performing RS encoding on a digital multimedia broadcast signal in a first direction based on an RS coding scheme and outputting a result in a second direction. An encoder, an AV data signal encoder for receiving and encoding an AV data signal from the FEC encoder, a parity data signal encoder for receiving and encoding a parity data signal from the FEC encoder, and at least one of the encoded signals. The present invention provides a digital multimedia broadcasting transmitter comprising a service mux for selecting and multiplexing.

Therefore, it is compatible with the conventional digital multimedia broadcasting transmission and reception system, and has an effect of improving error correction capability to secure an error rate required for data service even in a poor transmission channel environment.

Transmitter, receiver, error correction, parity data

Description

Digital Multimedia Broadcasting Transmitter and Receiver

1 is a diagram illustrating a conventional digital multimedia broadcasting transmitter.

2 is a diagram for explaining a conventional digital multimedia broadcasting receiver.

3 is a diagram for explaining a digital multimedia broadcasting transmitter according to the present invention.

4 is a diagram illustrating an embodiment of a frame structure of an FEC encoder among digital multimedia broadcasting transmitters according to the present invention.

5 is a diagram for explaining a digital multimedia broadcasting receiver according to the present invention.

* Explanation of symbols for main parts of the drawings

320: DAB signal encoder 340: FEC encoder

350: AV data signal encoder 360: Parity data signal encoder

370: Service Mux 500: Service Demux

510: DAB signal decoder 520: AV data signal decoder

530: parity data signal decoder 540: FEC decoder

The present invention relates to a digital multimedia broadcasting transmitter and receiver, and more particularly, to a digital multimedia broadcasting transmitter and receiver for improving error correction capability of a terrestrial digital multimedia broadcasting system.

Digitalization of broadcasts has also affected existing analog radio broadcasts, which has led to the advent of digital radio broadcasts. In addition to existing voice radio services, digital multimedia broadcasting (DMB), which includes data transmission and multimedia services, has become possible. The digital multimedia broadcasting is robust against noise and distortion on a transmission channel, has a high transmission efficiency, and has various advantages of enabling various multimedia services.

Digital multimedia broadcasting (DMB) is based on Eureka-147 digital radio broadcasting (DAB), which has been adopted as the terrestrial radio standard. In the digital multimedia broadcasting transmission system structure, a channel through which data is transmitted is called a main service channel (“MSC”).

Referring to Figure 1, a conventional digital multimedia broadcasting transmitter is described as follows.

The digital radio broadcasting (DAB) service is encoded by the source encoder 101 and then the energy of the signal is distributed via the energy diffuser 102. The convolutional encoder 105 encodes to correct a random error of a channel, and the time interleaving unit 107 distributes data in time.

A digital multimedia broadcasting (DMB) service is encoded by a separate A / V source encoder 111, and RS structures 113 and convolutional interleaving unit 115 that are resistant to aggregation errors on channels are newly added. Subsequently, it passes through the energy diffuser 117, the convolutional encoder 119, and the time interleaving unit 121 in the same manner as a conventional DAB system.

The two service data are mixed into one stream via the service MUX 123, and the block assembler 125 divides the data into OFDM symbol units. The QPSK mapper 127 converts the received data into a Quadrature Phase Shift Keying (QPSK) signal, and the frequency interleaving unit 129 distributes the QSPK signal in the frequency domain. The differential encoder 131 differentially encodes a QSPK signal in two adjacent OFDM symbols, and is finally converted to a baseband digital multimedia broadcasting (DMB) signal by the OFDM modulator 133.

Referring to Figure 2, a conventional digital multimedia broadcasting receiver will be described.

The digital multimedia broadcasting receiver has a structure corresponding to the digital multimedia broadcasting transmitter.

The received and synchronized digital multimedia broadcasting (DMB) signal is restored to the frequency domain signal through the OFDM demodulator 201, and the differential decoder 203 recovers the QPSK signal transmitted from two adjacent OFDM symbols. The frequency deinterleaving unit 205 restores the distributed QPSK symbols from the digital multimedia broadcasting transmitter to their original positions, the QPSK demapper 207 converts the QPSK symbols into a data stream, and the block de-assembler 209 is a unit of OFDM symbols. Restore the data separated by to the original stream.

The signal output from the block deassembler 209 is input to the service demux 210 to demultiplex the signal multiplexed by the transmitter into a DAB service signal and a DMB service signal.

The DAB service signal output from the service demux 210 restores data distributed in the time domain in the original order in the time deinterleaving unit 211, and random error of the channel in the convolutional decoder 213. Decoding the convolutional code to correct the signal, restoring the energy of the signal distributed in the energy collector 215, and decoding the source in the source decoder 217, the digital radio broadcasting (DAB) service is provided.

On the contrary, the DMB service signal output from the service demux 210 restores the data distributed in the time domain by the time deinterleaving unit 221 in the original order, and the convolutional decoder 223 decompresses the channel. Decode the convolutional coded to correct the random error, restore the energy of the signal dispersed in the energy collector 225 to the original, convolutional deinterleaving in the convolutional de-interleaver 227, the RS decoder 229 After RS decoding, the AV source decoder 231 finally decodes the AV source to provide a digital multimedia broadcasting (DMB) service.

However, the above-mentioned conventional digital multimedia broadcasting transmitter and receiver have the following problems.

Conventional digital multimedia broadcasting system is limited in error correction ability when data transmission for receiving digital multimedia broadcasting service becomes difficult due to error in transmission channel due to change of service type or worsening of transmission condition. There was.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide a digital multimedia broadcasting transmitter and receiver with improved error correction capability while maintaining full compatibility with conventional digital multimedia broadcasting transmission and reception systems.

In order to achieve the above object, the present invention provides a digital audio broadcast signal encoder for encoding a digital audio broadcast signal, and performs RS coding on a digital multimedia broadcast signal in a first direction based on an RS coding scheme, and performs a second direction. An FEC encoder for outputting the result, an AV data signal encoder for receiving and encoding an AV data signal from the FEC encoder, a parity data signal encoder for receiving and encoding a parity data signal from the FEC encoder, and the encoding. It provides a digital multimedia broadcasting transmitter comprising a service mux for selecting and multiplexing at least one or more of the received signals.

In another aspect, the present invention provides a service demux for demultiplexing the input service signal to output at least one signal, a digital audio broadcast signal decoder for decoding the digital audio broadcast signal output from the service demux, and the service An AV data signal decoder for decoding the AV data signal output from the demux, a parity data signal decoder for decoding the parity data signal output from the service demux, and a parity data signal decoded by the parity data signal decoder And a FEC decoder configured to receive an error and perform error correction of the AV data signal decoded by the AV data signal decoder.

The FEC encoder divides the input digital multimedia broadcasting signal data string into frame units, and performs parity data by performing RS encoding in the horizontal direction on the data bytes in each frame, and then parity data in the vertical direction. It is preferable to output separately.

Therefore, according to the present invention, it is compatible with the conventional digital multimedia broadcasting transmission and reception system, and it is possible to improve the error correction capability in order to secure the error rate required for data service even in a poor transmission channel environment.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention that can be specifically realized for the above purpose.

Referring to FIG. 3, an embodiment of a digital multimedia broadcasting transmitter according to the present invention will be described.

The digital multimedia broadcasting (DMB) transmitter according to the present invention includes a digital audio broadcasting (DAB) signal encoder 320, an FEC encoder 340, an AV data signal encoder 350, and a parity data signal encoder 360. ) And the service mux 350.

The DAB signal encoder 320 receives the digital audio broadcasting service (DAB service) and an energy diffuser 321 and the energy diffuser 321 for dispersing energy of a signal output from a source encoder 310 encoding a source. And a time interleaving unit 325 for interleaving the signals output from the convolutional encoder 323 with respect to time.

The FEC encoder 340 receives the source-coded output from the AV source encoder 330 of the transmitter and performs RS encoding on the digital multimedia broadcasting signal in the first direction based on the RS encoding method, and as a result, in the second direction. Outputs

The FEC encoder 340 divides the input digital multimedia broadcasting signal data stream into frame units, and performs parity data by performing RS encoding in the horizontal direction on the data bytes in each frame, and then in the vertical direction. It separates and outputs parity data.

In addition, the output of the FEC encoder 340 includes an AV data output through which input data is passed as it is, and a parity data output including parity bytes that are a result of performing an RS encoding process.

An embodiment of a frame structure of an FEC encoder among digital multimedia broadcasting transmitters according to the present invention will be described with reference to FIG. 4.

In FIG. 4, as many as 192 frames of n bytes are stored in a column sequence, RS coding is performed on 192 bytes of horizontal rows having the same order in each frame to generate parity data of 16 bytes. do.

Then, the output of the FEC encoder 340 is again sent out in the order of the column. By doing so, the FEC encoder 340 has the same effect as the virtual interleaving process.

Accordingly, the output of the FEC encoder 340 needs to be allocated with different transmission channels for the AV data signal output and the parity data output.

The AV data signal output from the FEC encoder 340 is input to the AV data signal encoder 350.

In this case, the AV data signal encoder 350 includes an RS encoder 351 for RS encoding the AV data signal output from the FEC encoder 340, and a convolutional interleaving unit 353 for convolutionally interleaving the RS coded signal. And an energy spreader 355 for energy spreading the convolutional interleaved signal, a convolutional encoder 357 for convolutionally encoding the energy spread signal, and a time interleaving unit 359 for interleaving the convolutional encoded signal. It is composed.

In contrast, the parity data signal output from the FEC encoder 340 is input to the parity data signal encoder 360.

In this case, the parity data signal encoder 360 may include an RS encoder 361 for RS coding the parity data signal output from the FEC encoder 340, and a convolutional interleaving unit 363 for convolutionally interleaving the RS coded signal. An energy diffuser 365 for energy spreading the convolutional interleaved signal, a convolutional encoder 367 for convolutionally encoding the energy spread signal, and a time interleaving 369 for interleaving the convolutional encoded signal; It is composed.

The digital audio broadcast service signal output from the DAB signal encoder 320 and the parity data signal output from the parity data signal encoder 360 and the AV data signal from the AV data signal encoder 350 are the service mux. (MUX) 350 is input.

The service mux 350 selects and multiplexes at least one of encoded and input service signals. That is, in the present invention, the service to be sent can be selected by the transmitting end. For example, when three signals are sent, the service mux 350 multiplexes three signals and outputs them as one stream.

Accordingly, the conventional digital multimedia broadcasting receiver cannot decode the parity data signal, but the present invention is compatible with the conventional digital multimedia broadcasting receiver because there is no problem in the receiver operation for receiving other services such as the digital audio broadcasting service.

5, a digital multimedia broadcasting receiver according to the present invention will be described.

The digital multimedia broadcasting receiver according to the present invention includes a service demux (500), a digital audio broadcasting (DAB) signal decoder 510, an AV data signal decoder 520, a parity data signal decoder 530, It characterized in that it comprises a FEC decoder 540.

When the digital multimedia broadcasting service signal is input to the digital multimedia broadcasting receiver, a process such as OFDM demodulation, differential decoding, frequency deinterleaving, QPSK demapping, block deassembly, and the like is performed, and then the service signal is input to the service demux 500. do.

The service demux 500 demultiplexes the input service signal and outputs at least one signal. In this embodiment, the service demux 500 outputs a DAB signal, an AV data signal, and a parity data signal.

First, the DAB signal output from the service demux 500 is input to the DAB signal decoder 510 to deinterleave the time inverse interleaving unit 501, and a convolutional decoder for convolutionally decoding the deinterleaved signal ( 513 and an energy collector 515 to collect energy of the convolutional decoded signal.

The signal output from the DAB signal decoder 510 is source-decoded by the source decoder 550 to provide a DAB service.

The AV data signal output from the service demux 500 is input to the AV data signal decoder 520.

In this case, the AV data signal decoding unit 520 includes a time deinterleaving unit 521 for time deinterleaving the input AV data signal, a convolutional decoder 523 for convolutionally decoding the deinterleaved signal, and the convolutional decoding. An energy collector 525 for energy collecting the collected signal, a convolutional deinterleaving unit 527 for conversely interleaving the collected energy signal, and an RS decoder 529 for RS decoding the convolutional deinterleaved signal. It is configured together.

The parity data signal output from the service demux 500 is input to the parity data signal decoder 530. The parity data signal is additional parity data.

In this case, the parity data signal decoder 530 may include a time deinterleaving unit 531 for deinterleaving the parity data signal input from the service demux 500, and a convolutional decoder for convolutionally decoding the deinterleaved signal. 533, an energy collector 535 for energy collecting the convolutional decoded signal, a convolutional deinterleaving unit 537 for conversely deinterleaving the energy collected signal, and an RS for RS decoding the convolutional deinterleaved signal. And a decoder 539.

The signal output from the AV data signal decoder 520 is decoded by an AV source by the AV source decoder 560 to provide a DMB service.

The FEC decoder 540 receives the AV data signal output from the AV data signal decoding unit 520 and the parity data signal output from the parity data signal decoding unit 530, and performs FEC decoding. The AV source is decoded at 570 to provide a DMB service with enhanced error correction capability.

That is, the parity data signal decoder 530 receives the decoded parity data signal and performs error correction on the AV data signal decoded by the AV data signal decoder 520.

Since the additional parity information for enhancing the error correction capability is received through a separate service channel, the conventional DMB receiver is not interrupted in restoring data and correcting an error in a conventional manner. In addition, the receiver according to the present invention can receive the digital multimedia broadcasting service with enhanced error correction capability through the FEC decoder 540 using additional parity information transmitted separately.

Therefore, since it does not interfere with the restoration of the digital audio broadcasting service and the digital multimedia broadcasting service, it maintains some compatibility with the conventional digital multimedia broadcasting system.

The present invention is not limited to the above-described embodiments, and can be modified by those skilled in the art as can be seen from the appended claims, and such modifications are within the scope of the present invention.

The effects of the digital multimedia broadcasting transmitter and receiver according to the present invention described above are as follows.

First, it is compatible with the conventional digital multimedia broadcasting transmission and reception system.

Second, the error correction capability was strengthened to secure the error rate required for data service even in a poor transmission channel environment.

Claims (7)

A digital audio broadcast signal encoder for encoding a digital audio broadcast signal; An FEC encoder for performing RS encoding on a digital multimedia broadcasting signal in a first direction based on an RS coding scheme and outputting a result in a second direction; An AV data signal encoder which receives and encodes an AV data signal from the FEC encoder; A parity data signal encoder which receives and encodes a parity data signal from the FEC encoder; And a service mux for selecting and multiplexing at least one or more of the encoded signals. The method of claim 1, wherein the FEC encoder, After dividing the input digital multimedia broadcasting signal data stream by frame unit, RS encoding is performed on the data bytes in each frame in the horizontal direction to generate parity data, and the parity data is separated and output in the vertical direction. Digital multimedia broadcast transmitter, characterized in that. The method of claim 1, wherein the AV data signal encoder, An RS encoder for RS encoding the AV data signal output from the FEC encoder, a convolutional interleaving unit for convolutionally interleaving the RS coded signal, an energy diffuser for energy diffusion of the convolutional interleaved signal, and the energy spread signal And a time interleaving unit for interleaving the convolutional coded signal. The method of claim 1, wherein the parity data signal encoder, An RS encoder for RS encoding the parity data signal output from the FEC encoder, a convolutional interleaving unit for convolutionally interleaving the RS encoded signal, an energy diffuser for energy diffusion of the convolutional interleaved signal, and the energy spread signal And a time interleaving unit for interleaving the convolutional coded signal. A service demux for demultiplexing an input service signal and outputting at least one signal; A digital audio broadcast signal decoder for decoding the digital audio broadcast signal output from the service demux; An AV data signal decoder for decoding the AV data signal output from the service demux; A parity data signal decoder for decoding the parity data signal output from the service demux; And an FEC decoder configured to receive the parity data signal decoded by the parity data signal decoder and perform error correction of the AV data signal decoded by the AV data signal decoder. The method of claim 5, And the parity data signal output from the service demux and input to the parity data signal decoder is additional parity data. The method of claim 5, wherein the RS data signal decoding unit, A time deinterleaving unit for deinterleaving the RS data signal inputted from the service demux, a convolutional decoder for convolutionally decoding the deinterleaved signal, an energy collector for energy collecting the convolutional decoded signal, and the energy collected And a convolutional deinterleaving unit for convolutional deinterleaving the signal and an RS decoder for RS decoding the convolutional deinterleaved signal.

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