KR20110047168A - Apparatus and method for multimedia data multiplexing - Google Patents

Abstract

PURPOSE: An apparatus and method for multiplexing multimedia data are provided to variably multiplex multimedia data based on the size of a packet determined according to the attribute of the multimedia data. CONSTITUTION: Based on the attributed of multimedia data, a multiplexing control unit(520) determines the size of a packet variably. The multiplexing control unit determines an FEC(Forward Error Correction) type of the multimedia data variably. Based on the determined size and FEC of the packet, PSI(Program Specification Information) generation unit(540) generates PSI(Program Specification Information) data. A multiplexing unit(550) multiplexes the multimedia data and the PSI data respectively.

Description

Apparatus and method for multimedia data multiplexing {APPARATUS AND METHOD FOR MULTIPLEXING OF MULTIMEDIA DATA}

The present invention relates to an apparatus and method for multiplexing multimedia data. The present invention relates to a technique for multiplexing and providing multimedia data such as video data, audio data, and text data.

1 is a view provided to explain the multiplexing of a conventional MPEG-2 system.

Referring to FIG. 1, the MPEG-2 system may multiplex a program including audio or video into program specific information (PSI) and elementary stream (ES). Here, the elementary stream may include any one of an audio stream, a video stream, and a data stream. The program detailed information may include a program map table (PMT), a program association table (PAT), and a network information table (NIT).

In general, the MPEG-2 system defines a transport stream (TS) packet having a fixed size of 188 bytes to multiplex compressed audio and video streams.

For example, referring to FIG. 2, the TS packet may include a header of 4 bytes and a body of 184 bytes. Herein, the header includes an 8-bit sync byte, a 1-bit transport error indicator field, and a 1-bit payload unit start indicator used for synchronizing TS packets. Field, 1-bit transport priority field, 13-bit PID (packet identifier), 2-bit transport scrambling control field, 2-bit adaptation field control field, and 4 It may include a continuity count field of bits. The body may include a payload of a stream to be actually transmitted.

At this time, in the case of MPEG 2, the length of the TS packet is fixed to 188 bytes as shown in FIG. Accordingly, the MPEG-2 system has a problem of increasing transmission overhead in transmitting high resolution multimedia data.

For example, in the case of Ultra High-Definition Television (UHDTV), multimedia data having a resolution of 4K or 8K is provided. In such a case of UHDTV, when the high-definition video data is to be compressed to transmit an elementary stream (ES), the MPEG-2 system packetizes the high-resolution video data into a plurality of MPEG-2 TS packets having a length of 188 bytes. Can transmit In this case, as shown in FIG. 3, a header and a Forward Error Correction (FEC) byte may be added and transmitted for each of the plurality of MPEGS-2 TS packets. In other words, as the size of the elementary stream increases, the number of divided MPEG-2 TS packets increases, and as the number of MPEG-2 TS packets increases, transmission is performed due to the header and FEC bytes of packets inserted for each MPEG-2 TS packet. Overhead can be increased.

In particular, in the case of audio data, the MPEG-2 system may packetize and transmit audio data in units of an access unit (AU). In general, audio data has a smaller size of the elementary stream than video data. However, like the video data, the MPEG-2 system multiplexes audio data into MPEG-2 TS packets having a length of 188 bytes and transmits them. In other words, the MPEG-2 system multiplexes audio data and video data into MPEG-2 TS packets of the same size and transmits the same. For this reason, there exists a problem that a transmission efficiency falls.

Accordingly, there is a need for a multimedia data multiplexing technique that can reduce transmission overhead and improve transmission efficiency incurred during multimedia data transmission.

The present invention provides a method and apparatus for variably multiplexing and transmitting multimedia data such as video data, audio data, and text data.

An apparatus for multiplexing multimedia data according to an embodiment of the present invention may be configured to variably determine a size of a packet based on attributes of multimedia data, and to variably determine an error correction coding (FEC) type of the multimedia data. The control unit may include a PSI generation unit generating PSI (Program Specification Information) data based on the determined packet size and the FEC type, and a multiplexer which multiplexes the multimedia data and the PSI data, respectively.

The multiplexer may variably determine the FEC type based on at least one of an attribute of the multimedia data and a characteristic of a transmission system.

The PSI generation unit may generate packet information including the determined packet size and packet identifier (PID) and FEC information including the FEC type, and insert the generated FEC information and the packet information into a PMT. Can be.

The PSI generator may generate a descriptor including the generated FEC information and the packet information.

The multiplexing control unit may variably determine the size of a packet of each of the plurality of multimedia data based on at least one of a compression rate and a resolution of the plurality of multimedia data when the types of the plurality of received multimedia data are the same. .

The multiplexing control unit variably determines the size of each packet of the plurality of multimedia data based on at least one of a kind, a compression ratio, and a resolution of the plurality of multimedia data when the types of the plurality of received multimedia data are different. Can be.

The apparatus may further include a packetization and FEC processing unit configured to packetize and FEC the PSI data and the multimedia data based on the packet size and the FEC type. Then, the multiplexer may multiplex the packetized and FEC processed PSI data and multimedia data.

The apparatus may further include a transmitter configured to separately transmit the multiplexed PSI data and the multiplexed multimedia data.

In addition, the multimedia data multiplexing method according to an embodiment of the present invention, variable size of the packet based on the attributes of the multimedia data, variable error correction coding (FEC) type of the multimedia data The method may include determining, generating PSI (Program Specification Information) data based on the determined packet size and the FEC type, and multiplexing the multimedia data and the PSI data, respectively.

The generating of the PSI data may include generating packet information including the determined packet size and packet identifier (PID) and FEC information including the FEC type, and generating the generated FEC information and the packet. Inserting information into the PMT.

The generating of the PSI data may generate a descriptor including the generated FEC information and the packet information.

In accordance with an aspect of the present invention, there is provided an apparatus for demultiplexing multimedia data, comprising: a data receiver configured to receive a PSI packet, wherein the PSI packet is packetized with PSI data based on packet information generated according to attributes of multimedia data; A PSI analyzer which acquires packet information and FEC information of the multimedia data based on the received PSI packet, a demultiplexer which demultiplexes the multiplexed multimedia data based on the packet information and the FEC information, and the FEC information And decoding the demultiplexed multimedia data to restore the multimedia data.

In the multimedia data demultiplexing method according to an embodiment of the present invention, receiving the PSI packet, wherein the PSI packet is packetized PSI data based on packet information generated according to an attribute of the multimedia data. Acquiring packet information and FEC information of the multimedia data based on the received PSI packet, and demultiplexing the multiplexed multimedia data based on the packet information and FEC information.

According to the present invention, the multimedia data can be variably multiplexed and transmitted based on the size of the packet determined according to the attributes of the multimedia data.

In addition, according to the present invention, by variably multiplexing the multimedia data, it is possible to reduce transmission overhead and improve transmission efficiency.

In addition, by transmitting the multimedia data using a suitable FEC coding scheme according to the determined packet size, it is possible to reduce the reception complexity of the multimedia data.

1 is a view provided to explain the multiplexing of a conventional MPEG-2 system.
2 is a diagram provided to explain a header structure of a conventional MPEG-2 TS packet.
3 is a diagram provided to explain a configuration of transmitting and inserting an FEC byte into a conventional MEGPS-2 TS packet.
4 is a diagram provided to explain multimedia data input to a multimedia data multiplexing apparatus according to an embodiment of the present invention.
5 is a block diagram showing the configuration of an apparatus for multiplexing multimedia data according to an embodiment of the present invention.
FIG. 6 is a view provided to explain a configuration of determining a packet size in a multimedia data multiplexing apparatus according to an embodiment of the present invention.
7 illustrates an example of an FEC code table according to an embodiment of the present invention.
8 is a flowchart provided to explain an operation of a multimedia multiplexing device according to an embodiment of the present invention.
9 is a block diagram illustrating a configuration of an apparatus for demultiplexing multimedia data according to an embodiment of the present invention.
10 is a flowchart provided to explain an operation of a multimedia data demultiplexing apparatus according to an embodiment of the present invention.
FIG. 11 is a diagram provided to explain a configuration of inserting packet information and FEC information into a PMT according to an embodiment of the present invention.

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

4 is a diagram provided to explain multimedia data input to a multimedia data multiplexing apparatus according to an embodiment of the present invention.

According to FIG. 4, the multimedia data multiplexing apparatus 420 may receive various types of multimedia data 410. Here, the multimedia data may include video data 411, audio data 412, still image data 413, and text data 414. In this case, the multimedia data multiplexing apparatus 420 may receive one or more compressed multimedia data from an audio encoding apparatus, a video encoding apparatus, or a storage device. Then, the multimedia data multiplexing apparatus 420 may multiplex the multimedia data and convert the multimedia data into data, packets, or streams that can be transmitted through radio waves.

5 is a block diagram showing the configuration of an apparatus for multiplexing multimedia data according to an embodiment of the present invention.

Referring to FIG. 5, the multimedia data multiplexing apparatus 500 includes an encoder 510, a multiplexing controller 520, a packetization and FEC processor 530, a PSI generator 540, a multiplexer 550, and a transmitter. 560 may include. The multimedia data multiplexing apparatus 500 may receive one or more types of multimedia data of the same or different types and may perform packetization by dividing the received multimedia data into one or more packets.

First, the encoder 510 may encode multimedia data using a compression scheme such as MPEG-2.

The multiplexing control unit 520 may variably determine the size of the packet based on the attributes of the multimedia data. In other words, when one piece of multimedia data is input, the multiplexing control unit 520 may determine a packet size differently according to the attributes of the input multimedia data. In addition, when a plurality of multimedia data having different attributes are input, the multiplexing control unit 520 may determine different sizes of packets of the plurality of multimedia data.

Here, the attribute of the multimedia data may include a compression ratio, a resolution, and a type of the multimedia data. In this case, the multiplexing control unit 520 may determine the size of the packet within the range of optimizing the transmission efficiency and overhead according to the properties of the multimedia data.

In one example, the multiplexing control unit 520 may determine the size of the packet in proportion to the resolution of the multimedia data. In other words, as shown in FIG. 6, the UHD (Ultra High Definition) data 610> HD (High Definition) data 620> SD (Standard Definition) data 630> Radio having a high resolution of multimedia data has a high resolution. The size of the packet may be large in order of the data 640.

As another example, the multiplexing control unit 520 may variably determine the size of a packet according to the type of multimedia data. In this case, the multiplexing control unit 520 may determine a large packet size in the order of video data> audio data> text data.

As such, the multiplexing control unit 520 may not only determine the size of the packet using any one of the attributes of the multimedia data, but also determine the size of the packet using one or more of various attributes of the multimedia data. For example, when the types of the plurality of multimedia data are the same, the multiplexing control unit 520 may determine the size of a packet of the plurality of multimedia data based on at least one of a compression rate and a resolution of the plurality of multimedia data.

In addition, when the types of the plurality of multimedia data are different, the multiplexing control unit 520 may determine the size of a packet of the plurality of multimedia data based on at least one of a compression rate, a resolution, and a type of the plurality of multimedia data.

In addition, the multiplexing control unit 520 may determine a Forward Error Correction (FEC) type of the multimedia data based on at least one of the attributes of the multimedia data and the characteristics of the transmission system. Here, the FEC type includes a low density parity check code (LDPC), a reed solomon (RS), a turbo code, a raptor code, a trellis code such as a Viterbi code, and the like. It can include a variety of error correction coding techniques. In addition, the characteristics of the transmission system may include bandwidth and system throughput.

For example, when an error occurrence rate is large, the multiplexing control unit 520 may determine an error correction encoding technique that is resistant to errors, even though the complexity is high, as an FEC type.

As another example, when the channel state is bad or the throughput of the multimedia data multiplexing apparatus is low, the FEC type determination unit 520 may determine, as the FEC type of the multimedia data, an encoding method having a good error correction effect even if the computation amount is large.

As another example, when the channel state is good or the throughput of the multimedia data multiplexing device is large, the FEC type determination unit 520 may determine the FEC type as an encoding method having a small amount of computation.

As another example, the FEC type determiner 520 determines an FEC type encoding method having a larger amount of computation as the size of multimedia data, such as UHD and HD data, and the FEC type determiner 520, like SD and radio data. The smaller the size of the multimedia data, the less the amount of computation can be determined as the FEC type.

In addition, the FEC type determiner 520 may determine the FEC type according to whether the multimedia data is real-time data or non-real-time data.

The packetization and FEC processing unit 530 processes the Forward Error Correction (FEC) for the multimedia data and the PSI data based on the determined FEC type, and packetizes the FEC processed multimedia data and the PSI data based on the determined packet size, respectively. Can be.

For example, when the FEC type is determined by RS encoding, the packetization and FEC processing unit 540 may encode the multimedia data and the PSI data using RS encoding techniques, respectively. Similarly, when the FEC type is determined to be LDPC, turbo code, or raptor code, the packetization and FEC processing unit 540 may encode multimedia data and PSI data using LDPC, turbo code, or raptor code, respectively. have. In this case, the packetization and FEC processing unit 540 may encode multimedia data and PSI data by combining at least one error correction encoding technique.

The packetization and FEC processing unit 530 may packetize the FEC-processed multimedia data and the PSI data based on the size of the packet.

For example, the packetization and FEC processing unit 530 may divide the FEC processed multimedia data into a plurality of data packets according to the size of the packet. The packetization and FEC processing unit 540 may divide the FEC-processed PSI data into a plurality of PSI packets according to the size of the packet.

The PSI generator 540 may generate PSI (Program Specification Information) data based on the determined packet size and the FEC type. Where the PSI data is

In this case, the PSI generator 540 may generate packet information including the packet size determined by the multiplexing controller 520 and the packet identifier generated according to the packetization and the packetization by the FEC processing unit 540. The PSI generator 540 may generate FEC information including the FEC type and generate PSI data including the generated FEC information and packet information.

In more detail, the PSI generation unit 540 may define a specific field in a payload of PSI data, and specify a packet identifier (PID), a packet size, and an FEC type in the specified specific field. For example, as illustrated in FIG. 11, the PSI generation unit 540 packetizes the 540PSI generation unit 540 of MPEG-2, and the FEC processing unit 530 converts the generated PSI data into the FEC type and the packet as described above. Packetization and FEC processing can be performed based on the size of.

FECtype_descritpor ()
{
descriptor_tag
descriptor_length
TS_packet_length-(10)
FEC_type-(20)
}

According to Table 1, the packet size 10 and FEC type 20 may be specified in one descriptor. In this case, the PSI generator 540 may generate the PSI data by specifying the packet size and the FEC type in two descriptors, respectively.

In FIG. 11, a case where a packet size and an FEC type are inserted into a PMT defined by MPEG-2 has been described as an example. However, the packet size and FEC type have a structure or syntax having the format of FIG. 11 in addition to a PMT (Program Map Table). It can also be specified using (syntax).

The multiplexer 550 may multiplex the packetized and FEC processed multimedia data and the PSI data based on the determined packet size. Then, the transmitter 560 may separately transmit the multiplexed multimedia data and the PSI data. In other words, the transmitter 560 may transmit the multiplexed plurality of data packets and the plurality of PSI packets. In this case, the PSI packet may further include multiplexing information such as mapping information and program information in addition to the packet information and the FEC information. Here, the program information may include detailed information of a program to which multimedia data such as audio data, video data, and text data belong.

Meanwhile, the apparatus for multiplexing multimedia data according to an embodiment of the present invention may classify and code an FEC type in detail and include it in a PSI packet as shown in FIG. 7.

Up to now, in FIG. 5, the packetization and FEC processing unit 530 is described as being configured separately from the encoding unit 510 and the multiplexing unit 550. However, the packetization and FEC processing unit 530 includes the encoding unit 510 and the encoding unit. It may be included in any one of the multiplexer 550. In other words, the encoder 510 may packetize and FEC the multimedia data and the PSI data, respectively. Similarly, the multiplexer 550 may packetize and FEC the multimedia data and the PSI data, respectively.

8 is a flowchart provided to explain an operation of a multimedia multiplexing device according to an embodiment of the present invention.

First, in operation 810, the multiplexing control unit 520 may determine the size of a packet based on the attributes of the multimedia data. Here, the attribute of the multimedia data may include a compression ratio, a resolution, and a type of the multimedia data.

In this case, the multiplexing control unit 520 may variably determine the size of a packet used to divide the multimedia data into a plurality of packets according to the attributes of the multimedia data.

In operation 820, the multiplexing control unit 520 may determine a Forward Error Correction (FEC) type of the multimedia data based on at least one of attributes of the multimedia data and characteristics of the transmission system. Here, the characteristics of the transmission system may include bandwidth, and system performance.

In operation 830, the packetization and FEC processing unit 530 may packetize and FEC the multimedia data and the PSI data based on the determined FEC type. Here, the FEC type includes a low density parity check code (LDPC), a reed solomon (RS), a turbo code, a raptor code, a trellis code such as a Viterbi code, and the like. It can include a variety of error correction coding techniques.

In this case, the PSI generator 540 may generate packet information including the determined packet size and packet identifier. The PSI generator 540 may generate FEC information including the FEC type and generate PSI data including the generated FEC information and packet information. Here, the packet identifier may be used to identify the divided packets as the multimedia data or the PSI data is divided into a plurality of packets.

In operation 840, the multiplexer 540 may multiplex the multimedia data and the PSI data based on the size of the packet. In other words, the multiplexer 540 may multiplex the multimedia data divided into a plurality of packets through packetization. That is, the multiplexer 540 may multiplex a plurality of data packets. Similarly, the multiplexer 540 may multiplex the PSI data divided into a plurality of packets through packetization. That is, the multiplexer 540 may multiplex a plurality of PSI packets.

Then, in operation 850, the transmitter 560 may separately transmit the multiplexed multimedia data and PSI data. In other words, the transmitter 560 may transmit the multiplexed multimedia data and the PSI data separately without carrying the multiplexed PSI data together on the multiplexed multimedia data. In this case, the transmitter 560 may transmit the multiplexed multimedia data and PSI data together.

9 is a block diagram illustrating a configuration of an apparatus for demultiplexing multimedia data according to an embodiment of the present invention.

Referring to FIG. 9, the multimedia data demultiplexing apparatus 900 may include a data receiver 910, a PSI analyzer 920, a demultiplexer 930, and a data restorer 940.

The data receiver 910 may separately receive the multiplexed PSI data and the multimedia data from the multimedia data multiplexing apparatus 500. In this case, as the multiplexed PSI data is packetized and FEC processed by the multimedia data multiplexing apparatus 500, the data receiver 910 may receive a plurality of multiplexed data packets. Similarly, as the PSI data is packetized and FEC processed by the multimedia data multiplexing apparatus 500, the data receiver 910 may receive a plurality of multiplexed PSI packets. Here, the PSI packet may include packet information and FEC information.

The PSI analyzer 920 may obtain FEC information and packet information from the PSI packet. Here, the packet information may include the packet size and the packet identifier determined according to the attributes of the multimedia data, and the FEC information may include the FEC type.

The demultiplexer 930 may demultiplex the data packet and the PSI packet based on the obtained packet information and the FEC information. Then, the data recovery unit 940 may decode the demultiplexed data packet and the PSI packet based on the FEC information.

More specifically, the demultiplexer 930 may restore the encoded multimedia data by demultiplexing a plurality of data packets collected based on the packet identifier and the size of the packet. Then, the data recovery unit 940 may decode the encoded multimedia data reconstructed according to the FEC type included in the FEC information. As such, the data recovery unit 940 may restore original multimedia data input to the multimedia data multiplexing apparatus 500 through decoding.

10 is a flowchart provided to explain an operation of a multimedia data demultiplexing apparatus according to an embodiment of the present invention.

First, in operation 1010, the data receiver 910 may receive multiplexed PSI data and multimedia data separately transmitted from the multimedia data multiplexing apparatus 500. In other words, the data receiver 910 may receive a plurality of PSI packets and data packets. Here, the PSI packet may include packet information and FEC information.

In operation 1020, the PSI analyzer 920 may obtain packet information and FEC information from the PSI packet. In this case, the packet information may include a packet size and a packet identifier. Here, the packet size is determined according to the attributes of the multimedia data in the multimedia data multiplexing apparatus 500, and the packet identifier may be used to identify the divided data packets by dividing the multimedia data based on the size of the packet. . In addition, the FEC information may include the FEC type determined based on the characteristics of the transmission system in the multimedia data multiplexing apparatus 500.

In operation 1030, the demultiplexer 930 may demultiplex the plurality of data packets based on the FEC information and the packet information to restore the encoded multimedia data.

In operation 1040, the data reconstruction unit 940 may decode the encoded multimedia data reconstructed based on the obtained FEC information. The data recovery unit 940 may restore the original multimedia data through decoding. Then, the restored multimedia data may be stored in a storage device (not shown) or reproduced through a display (not shown).

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 those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

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

500: multimedia data multiplexing device
510: encoder
520: multiplexing control unit
530: packetization and FEC processing unit
540: PSI generation unit
550: multiplexer
560: transmission unit
900: multimedia data demultiplexer
910: data receiving unit
920: PSI analysis unit
930: demultiplexer
940: data recovery unit

Claims (20)

A multiplexing control unit variably determining a size of a packet based on attributes of multimedia data and variably determining an error correction coding (FEC) type of the multimedia data;
A PSI generation unit generating PSI (Program Specification Information) data based on the determined packet size and FEC type; And
A multiplexer which multiplexes the multimedia data and the PSI data, respectively
Multimedia data multiplexing device comprising a. The method of claim 1,
The multiplexer,
And variably determining the FEC type based on at least one of an attribute of the multimedia data and a characteristic of a transmission system. The method of claim 2,
The attribute of the multimedia data includes at least one of a compression ratio of the multimedia data, a resolution of the multimedia data, and a type of the multimedia data,
The characteristic of the transmission system, the multimedia data multiplexing device, characterized in that at least one of the bandwidth (bandwidth), and the system (throughput). The method of claim 1,
The PSI generation unit,
And generating packet information including the determined packet size and packet identifier (PID) and FEC information including the FEC type, and inserting the generated FEC information and the packet information into a PMT. Device. The method of claim 4, wherein
The PSI generation unit,
And generating a descriptor including the generated FEC information and the packet information. The method of claim 1,
The multiplexing control unit,
When the types of the plurality of multimedia data received are the same, the multimedia data multiplexing device is configured to variably determine the size of a packet of each of the plurality of multimedia data based on at least one of a compression rate and a resolution of the plurality of multimedia data. . The method of claim 1,
The multiplexing control unit,
When the types of the plurality of received multimedia data are different, multimedia data, characterized in that the size of the packet of each of the plurality of multimedia data is variably determined based on at least one of the type, compression rate and resolution of the plurality of multimedia data Multiplexing device. The method of claim 1,
Packetization and FEC processing unit for packetizing and FEC the PSI data and the multimedia data, respectively, based on the packet size and the FEC type
Further comprising:
The multiplexer,
And multiplexing the packetized and FEC processed PSI data and multimedia data. The method of claim 1,
Transmitter for separately transmitting the multiplexed PSI data and the multiplexed multimedia data
Multimedia data multiplexing device further comprising. Variably determining a size of a packet based on attributes of multimedia data;
Variably determining an error correction coding (FEC) type of the multimedia data;
Generating Program Specification Information (PSI) data based on the determined packet size and the FEC type; And
Multiplexing the multimedia data and the PSI data, respectively
Multimedia data multiplexing method comprising a. The method of claim 10,
The step of variably determining the FEC type,
Variably determining the FEC type for each multimedia data based on at least one of an attribute of the multimedia data and a characteristic of a transmission system,
The attribute of the multimedia data,
At least one of a compression rate of the multimedia data, a resolution of the multimedia data, and a type of the multimedia data,
The characteristic of the transmission system, the multimedia data multiplexing method, characterized in that at least one of the bandwidth (bandwidth), and the system (throughput). The method of claim 10,
Generating the PSI data,
Generating packet information including the determined packet size and a packet identifier (PID) and FEC information including the FEC type; And
Inserting the generated FEC information and the packet information into a PMT;
Multimedia data multiplexing method comprising a. The method of claim 12,
Generating the PSI data,
And generating a descriptor including the generated FEC information and the packet information. A data receiver for receiving a PSI packet, wherein the PSI packet is packetized with PSI data based on packet information generated according to attributes of multimedia data;
A PSI analyzer obtaining packet information and FEC information of the multimedia data based on the received PSI packet;
A demultiplexer for demultiplexing the multiplexed multimedia data based on the packet information and the FEC information; And
A data restoring unit configured to restore the multimedia data by decoding the demultiplexed multimedia data based on the FEC information;
Multimedia data demultiplexing device comprising a. The method of claim 14,
The demultiplexer,
Restoring the encoded multimedia data by demultiplexing the multiplexed multimedia data based on the packet information,
The data recovery unit,
And reconstructing the multimedia data as the decoded encoded multimedia data is decoded based on the FEC information. 16. The method of claim 15,
The packet information,
A packet identifier (PID) and a size of the multiplexed packet determined according to the attribute of the multimedia data,
And the FEC information comprises an FEC type determined based on at least one of an attribute of the multimedia data and a characteristic of a transmission system. The method of claim 14,
The attribute of the multimedia data,
And at least one of a compression ratio of the multimedia data, a resolution of the multimedia data, and a type of the multimedia data. Receiving a PSI packet, wherein the PSI packet is packetized PSI data based on packet information generated according to an attribute of multimedia data;
Obtaining packet information and FEC information of the multimedia data based on the received PSI packet; And
Demultiplexing the multiplexed multimedia data based on the packet information and the FEC information
Multimedia data demultiplexing method comprising a. The method of claim 18,
The demultiplexing step,
And restoring the encoded multimedia data according to the demultiplexing of the multiplexed multimedia data based on the packet information. The method of claim 18,
Restoring multimedia data by decoding the restored multiplexed multimedia data based on the FEC information;
Multimedia data demultiplexing method further comprising.

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