KR20050117314A - Apparauts and method for transmitting and receiving with reducing the setup time of data packet - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a transmission / reception apparatus and a method for reducing access delay time of a data packet.

2. The technical problem to be solved by the invention

According to the present invention, after transmitting table information including a program association table (PAT) and a program structure table (PMT) in advance, the information channel is a fast information channel having a relatively short access time and a fixed capacity channel. By transmitting through the (FIC), the transmission and reception apparatus for reducing the access delay time of the data packet for improving the transmission efficiency by reducing the access delay time of the data packet during the initial setting and the channel change in the receiving apparatus and a method thereof The purpose is to provide.

3. Summary of Solution to Invention

The present invention relates to a transmission apparatus for shortening the access delay time of a data packet, wherein a table including a program structure table (PMT) and a program association table (PAT) is analyzed from program characteristic information (PSI) of a transport stream (TS). Transport stream analysis means for deriving analysis information and frame configuration information to be transmitted through a fast information channel (FIC); External encoding means for reinforcing error tolerance of the transport stream TS; Storage means for storing a transport stream (TS) received from the external calling means; Frame management means for controlling the storage means and managing program structure table (PMT) and program association table (PAT) analysis information and frame configuration information derived from program characteristic information (PSI) received from the transport stream analysis means. ; Frame configuration means for composing a frame using frame configuration information received from the frame management means, a transport stream TS received from the storage means, and a transport stream TS received from the outside; And frame transmitting means for transmitting the frame received from the frame constructing means.

Description

Apparauts and method for transmitting and receiving with reducing the setup time of data packet

The present invention relates to a transmission / reception apparatus for reducing access delay time of a data packet and a method thereof, and more particularly, a program association table (PAT) and a program structure table of a transport stream (TS). By transmitting a table including a program map table (PMT) in advance, the analyzed information is transmitted through a fast information channel (FIC), which is a channel having a short access time and a fixed capacity. The present invention relates to a transmission / reception apparatus for shortening the access delay time of a data packet and a method thereof.

Digital Multimedia Broadcasting (DMB) is defined as an audio service having a CD (Compact Disk) level audio quality and a digital multimedia broadcasting that provides a variety of additional data services and provides excellent fixed and mobile reception quality.

Digital Multimedia Broadcasting (DMB) has been called Digital Audio Broadcasting (DAB) in Europe and Canada, but digital audio broadcasting (DMB) is based on the International Telecommunication Union (ITU) regulations that DAB includes video and data in addition to audio. It was renamed as multimedia broadcasting (DMB).

In addition, digital multimedia broadcasting (DMB) can be broadly classified into terrestrial digital multimedia broadcasting (DMB) and satellite digital multimedia broadcasting (DMB) according to the characteristics of a medium, which is a means of transmission. In the case of satellite digital multimedia broadcasting (DMB), It can be divided into mobile services.

Terrestrial Digital Multimedia Broadcasting (DMB) improves error correction to enable video services while moving the Eureka-147 (European Reserch Coordination Agency project-147) standard of the existing digital audio broadcasting (DAB) system. This can be achieved by increasing the compression efficiency.

At this time, one method of synchronizing MPEG-4 data, which is multimedia data for digital broadcasting, to MPEG-2 data is transmitted. After receiving mp4 data, which is a storage format of MPEG-4 data, program information and MPEG-4 object data is converted into MPEG-2 format packets using synchronization information, and each packetized MPEG-4 data is multiplexed with MPEG-2 data for transmission.

In addition, one method of decoding MPEG-4 data, which is multimedia data, on the receiving side is to demultiplex the received transport stream (TS) to generate a program specific information (PSI) packet, a 14496 section packet, and an elementary stream packet. After separating into (PES: Packed Elementary Stream), the program characteristic information (PSI) analyzer, 14496 analyzer, and elementary stream packet (PES) analyzer analyze each packet and decode according to MPEG-4 standard.

The conventional method has been filed in the Republic of Korea Patent Publication No. 10-2002-0060908 'apparatus and method for synchronizing and transmitting the MPEG-4 data to the MPEG-2 data'.

1 is a configuration diagram of an exemplary embodiment of a conventional digital multimedia broadcasting (DMB) receiving apparatus.

As shown in FIG. 1, a conventional digital multimedia broadcasting (DMB) receiver includes a radio frequency (RF) receiver 101, a channel decoder 102, a fast information channel (FIC) analyzer 103, and a main service channel. A main service channel (MSC) data processing unit 104, an external decoding unit 105, a demultiplexer 120, a program characteristic information (PSI) analysis unit 110, and a post-receipt processing unit 100.

In this case, the reception post-processing unit 100 may include an initial object descriptor (IOD) analyzer 130, an 14496 section analyzer 140, an elementary stream packet (PES) analyzer 150, and MPEG-4 audio. And an audio / video (AV) processing unit 160.

The RF receiver 101 receives a digital multimedia broadcasting RF signal and demodulates it into an IF (Intermediate Frequency) signal, and the channel decoder 102 converts the received IF signal into fast information channel (FIC) data and a main service channel ( MSC) data.

In this case, the fast information channel (FIC) is an information channel for quick access and delivers control information necessary to interpret the configuration of multiplexed information, service information, and main service channel (MSC) data, and the main service channel (MSC) As a main service channel for multiplexing service components corresponding to each service according to a multiplexing structure established through a fast information channel (FIC), MPEG audio data and various additional data are multiplexed and transmitted to the main service channel (MSC).

In particular, in the digital multimedia broadcasting (DMB) standard, an MPEG-2 transport stream (TS) encapsulated in MPEG-4 audio / video is multiplexed and transmitted through the main service channel (MSC).

The fast information channel (FIC) analyzer 103 analyzes multiplexed information and service information from the fast information channel (FIC) data separated by the channel decoder 102.

The main service channel (MSC) data processor 104 separates the main service channel (MSC) separated from the channel decoder 102 by using the multiplexing information and the service information interpreted by the fast information channel (FIC) analyzer 103. Separate only the transport stream (TS) carrying MPEG-4 audio / video from the data.

The outer decoding unit 105 performs additional channel decoding on the transport stream TS separated by the main service channel (MSC) data processing unit 104 according to the digital multimedia broadcasting (DMB) standard.

The demultiplexer 120 demultiplexes the transport stream TS decoded by the outer decoder 105 into a program characteristic information (PSI) packet, a 14496 section packet, and a basic strip packet (PES).

The program characteristic information (PSI) analyzer 110 receives the program characteristic information (PSI) packet separated by the demultiplexer 120 and interprets the packet to generate an initial object descriptor (IOD).

In this case, the initial object descriptor (IOD) is the first packet of an object descriptor (OD) stream, and is an elementary stream identifier (ES_ID) of a scene description (SD) and an object descriptor (OD). ) By connecting the two values. That is, since the initial object descriptor (IOD) acts as an access point, it cannot be packetized into a sync layer (SL) packet.

Thus, the initial object descriptor (IOD) is the first descriptor of the program structure table (PMT) section before MPEG-4 data is found when MPEG-4 data is encapsulated in an MPEG-2 transport stream (TS) and transmitted. ) Is encapsulated in a loop and sent on it.

The initial object descriptor (IOD) analyzer 130 receives an initial object descriptor (IOD) from the program characteristic information (PSI) analyzer 110 to generate initial object descriptor (IOD) data.

The 14496 section analyzer 140 receives the 14496 section packet from the demultiplexer 120 and interprets the 14496 section packet to generate an MPEG-4 Object Descriptor (OD) / BIFS (Binary Format For Scene) sink layer (SL) packet. do.

The elementary stream packet (PES) analyzer 150 receives the elementary stream packet (PES) from the demultiplexer 120 and interprets the elementary stream packet (PES) to generate an MPEG-4 audio / video sync layer (SL) packet.

The MPEG-4 audio / video (AV) processor 160 receives initial object descriptor (IOD) data from the initial object descriptor (IOD) analyzer 130 and the 14496 section interpreter 140 and MPEG-4 packets are received from the elementary stream packet (PES) analyzer 150 to decode according to the MPEG-4 standard to generate audio / video.

However, if the audio / video data is decoded through the above process, the MPEG-4 packet is encapsulated in the MPEG-2 transport stream (TS) when the receiver is initially set up or when the broadcasting channel is changed. The time can be longer compared to other broadcast systems.

In addition, the Digital Multimedia Broadcasting (DMB) standard additionally performs Reed Solomon (RS) encoding and external encoding of convolutional interleaving to prevent transmission channel error. The access delay time of the -4 packet is longer.

The present invention has been proposed in order to solve the above problems, and after analyzing the table information including the program association table (PAT) and program structure table (PMT) in advance, the access time is relatively compared to the analyzed analysis information. By transmitting through the fast information channel (FIC), which is a short and fixed capacity channel, the access delay time of the data packet is shortened to increase the transmission efficiency by shortening the access delay time of the data packet upon initial setting and channel change at the receiving device. An object of the present invention is to provide a transmission / reception apparatus and a method thereof.

A transmission apparatus of the present invention for achieving the above object is a program structure table (PMT) and a program association table from a program characteristic information (PSI) of a transport stream (TS) in a transmission apparatus for shortening an access delay time of a data packet. Transport stream analysis means for analyzing a table including the PAT to derive analysis information and frame configuration information to be transmitted through a fast information channel (FIC); External encoding means for reinforcing error tolerance of the transport stream TS; Storage means for storing a transport stream (TS) received from the external calling means; Frame management means for controlling the storage means and managing program structure table (PMT) and program association table (PAT) analysis information and frame configuration information derived from program characteristic information (PSI) received from the transport stream analysis means. ; Frame configuration means for composing a frame using frame configuration information received from the frame management means, a transport stream TS received from the storage means, and a transport stream TS received from the outside; And frame transmitting means for transmitting the frame received from the frame constructing means.

In addition, the transmission method of the present invention, in the transmission method for reducing the access delay time of the data packet, by analyzing a table including a program structure table (PMT) and a program association table (PAT) from the program characteristic information (PSI) A transport stream analysis step of deriving analysis information and frame configuration information to be transmitted through a fast information channel (FIC); An external encoding step of enhancing error tolerance of the transport stream TS; A frame construction step of constructing a frame using the analysis information, the frame configuration information, a transport stream (TS) with enhanced error tolerance, and a transport stream (TS) received from the outside; And a frame transmission step of transmitting the configured frame.

On the other hand, the receiving device of the present invention, the receiving device for reducing the access delay time of the data packet, the receiving device for receiving an external RF (RF) signal; Channel decoding means for separating the signal received from the receiving means into fast information channel (FIC) data and main service channel (MSC) data; Parsing the fast information group (FIG) field from the fast information channel (FIC) data received from the channel decoding means, and deriving the configuration information including the program association table (PAT) and program structure table (PMT) analysis information. Fast information channel (FIC) analysis means; Primary service channel (MSC) data processing means for separating the information stream TS from the main service channel (MSC) data received from the channel decoding means using the configuration information received from the fast information channel (FIC) analyzing means. ; Outer decoding means for additionally channel decoding the information stream TS received from the main service channel (MSC) data processing means; Demultiplexing means for demultiplexing the information stream TS received from the outer decoding means by using the configuration information received from the fast information channel (FIC) analyzing means; And post-processing means for analyzing and decoding the configuration information and the information stream TS received from the fast information channel (FIC) analyzing means and the demultiplexing means.

In addition, the receiving method of the present invention, in the receiving method for reducing the access delay time of the data packet, a channel for receiving the RF (RF) signal and separating the information channel (FIC) data and the main service channel (MSC) data Decoding step; A quick information channel (FIC) for deriving configuration information including a program association table (PAT) and a program structure table (PMT) analysis information by analyzing a quick information group (FIG) field from the separated quick information channel (FIC) data. ) Interpretation step; A main service channel (MSC) data processing step of separating an information stream TS from the separated main service channel (MSC) data using the configuration information; An outer decoding step of additionally channel decoding the information stream TS; A demultiplexing step of demultiplexing the outer decoded information stream TS using the configuration information; And a post-receiving step of analyzing and decoding the configuration information and the information stream TS.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a diagram illustrating an embodiment of a transmitting apparatus for shortening an access delay time of a data packet in a digital multimedia broadcasting (DMB) system according to the present invention.

As shown in FIG. 2, the transmission apparatus according to the present invention includes a transport stream (TS) analyzer 210, an external encoder 220, a storage 230, and an ETI frame driver 240. , An ETI frame constructing unit 250 and an ETI frame transmitting unit 260.

In this case, ETI (Ensemble Transport Interface) is a standard for transmitting Digital Multimedia Broadcasting (DAB) Ensemble, which is an output of a digital multimedia broadcasting (DAB) multiplexer, through a network, and is defined in the European Telecommunications Standard (ETS) 300 799. have.

The transport stream analysis unit 210 calculates an effective data rate by analyzing program characteristic information (PSI) data of a stream that is encoded in MPEG-4 and then encapsulated and transmitted in an MPEG-2 transport stream (TS). Derived information for frame composition is output to the ETI frame manager 240.

In particular, table information including a program association table (PAT) and a program structure table (PMT) is analyzed from program characteristic information (PSI) data, and necessary information is derived and output to the ETI frame manager 240.

The outer coder 220 is encoded in MPEG-4 and is then encapsulated in a transport stream TS to enhance the error resistance of the transmitted stream and output it to the storage 230.

The storage unit 230 stores the transport stream TS having enhanced error tolerance in the external encoder 220 under the control of the ETI frame manager 240.

The ETI frame manager 240 manages all parts related to the ETI frame configuration. In particular, the analysis information obtained by analyzing a table including a valid data rate, a program association table (PAT), and a program structure table (PMT) is received from the transport stream (TS) analyzer 210 to the ETI frame configuration unit 250. The amount of transport stream (TS) necessary for composing one ETI frame is determined by using the received effective data rate and outputted to the ETI frame configuration unit 250. In addition, the storage unit 230 is controlled.

In this case, the ETI frame manager 240 may receive information necessary for constructing an ETI frame through a graphic user interface (GUI) from the system manager, or may receive configuration information regarding a transport stream (TS).

The ETI frame configuration unit 250 may determine an amount of a transport stream TS, a program association table (PAT), and a program structure table (PMT) required to configure one ETI frame received from the ETI frame manager 240. The transport stream TS is read from the storage unit 230 using the analysis information obtained by analyzing the included table to construct an ETI frame.

In addition, the ETI frame configuration unit 250 receives the Eureka-147 based DAB stream from the outside using the information received from the ETI frame manager to configure the ETI frame.

A detailed description of the ETI frame configuration unit 250 will be described later with reference to FIG. 3.

The ETI frame transmitter 260 receives an ETI frame from the EIT frame constructor 250 and converts the ETI frame into a physical form.

FIG. 3 is a detailed block diagram of an embodiment of a frame structure of a transmitting apparatus for reducing an access delay time of a data packet in a digital multimedia broadcasting (DMB) system according to the present invention.

In the Eureka-147 digital audio broadcasting (DAB) transmission frame, a fast information channel (FIC) band is fixedly allocated to about 4% of the total transmission payload data according to each transmission mode. In the case of MPEG-4 service, considering random access, random access time is important because fast information channel (FIC) does not apply time interleaving in Eureka-147 digital audio broadcasting (DAB) system. Shorter than the access time of the service channel (MSC).

As shown in FIG. 3, the ETI frame configuration unit 250 according to the present invention includes an ETI field configuration unit 310, a fast information channel (FIC) configuration unit 320, and a main service channel (MSC) configuration unit 330. ) And a multiplexer 340.

The ETI frame configuration unit 250 is the amount of transport stream (TS) required to configure one ETI frame from the ETI frame manager 240, the ETI frame configuration field value, the program association for the fast information channel (FIC) configuration Analysis information analyzing a table including a table (PAT) and a program structure table (PMT) and a scheduling signal for transmitting the configured ETI frame to have a transmission period suitable for the standard are received.

In addition, the storage unit 230 receives the transport stream (TS), and receives a digital multimedia broadcasting (DAB) stream from the outside.

The ETI field configuration unit 310 configures an ETI frame configuration field by using the ETI frame configuration field value received from the ETI frame manager 240.

The fast information channel (FIC) configuration unit 320 configures a fast information channel (FIC) by using the fast information channel (FIC) configuration information received from the ETI frame manager 240. That is, a new fast information group (FIG) field is configured by using analysis information obtained by analyzing a table including a program association table (PAT) and a program structure table (PMT).

The main service channel (MSC) configuration unit 330 is transmitted from the storage unit 230 and the outside by the amount of transport stream (TS) required to configure one ETI frame received from the ETI frame manager 240. A stream TS is read and a main service channel MSC is configured using the configuration information received from the ETI frame manager 240.

The multiplexer 340 multiplexes data received from the ETI field component 310, the fast information channel (FIC) component 320, and the main service channel (MSC) component 330 to complete an ETI frame. The completed ETI frame is output to the ETI frame transmitter 260.

4 is a diagram illustrating an embodiment of configuring a new quick information group (FIG) field using program association table (PAT) and program structure table (PMT) analysis information.

The fast information channel (FIC) configuration unit 320 of the ETI frame configuration unit 250 utilizes a new fast information channel (PAT) and program structure table (PMT) analysis information received from the ETI frame manager 240. Configure an information group (FIG) field.

As shown in FIG. 4, a program number constituting the program association table (PAT) information or an initial object descriptor (IOD) and a sink layer (SL) descriptor constituting the program structure table (PMT) information. Descriptor loops, such as descriptors, are each included in a new type of fast information group (FIG) field.

The multiplexer 340 multiplexes the new quick information group (FIG) field and outputs it to the ETI frame transmitter 260, and the ETI frame transmitter 260 transmits the new quick information group (FIG) field to a fast information channel (FIG). Insert into the FIC).

FIG. 5 is a diagram illustrating an embodiment of a receiving apparatus for shortening an access delay time of a data packet in a digital multimedia broadcasting (DMB) system according to the present invention.

As shown in FIG. 5, the reception apparatus according to the present invention includes an RF receiver 501, a channel decoder 502, a fast information channel (FIC) analyzer 503, and a main service channel (MSC) data processor 504. , An external decoding unit 505, a demultiplexer 510, and a reception post-processing unit 500.

The RF receiver 501, the channel decoder 502, the main service channel (MSC) processing unit 504, the outer decoding unit 505, and the post-receipt processing unit 500 described in FIG. Since the receiver 101, the channel decoder 102, the main service channel (MSC) data processor 104, the outer decoder 105, and the post-receiver 100 perform the same functions, they will not be described herein again.

Meanwhile, the conventional fast information channel (FIC) analyzer 103 analyzes multiplexed information and service information from the fast information channel (FIC) data separated by the channel decoder 102, and interprets the analyzed information as the main service channel (MSC). ) Is output to the data processing unit 104.

However, the fast information channel (FIC) analysis unit 503 of the receiving apparatus according to the present invention is a program association table (PAT) and program structure table (PMT) in the fast information channel (FIC) data separated by the channel decoder 502. Interpret new Quick Information Group (FIG) field data with analysis information that analyzes a table that contains a table, including program number, initial object descriptor (IOD), sink layer (SL) descriptor, etc. After deriving the transport stream TS configuration information and the initial object descriptor (IOD) configuration information, the demultiplexer 510 and the initial object descriptor (IOD) analyzer 510 are output.

In addition, the fast information channel (FIC) analysis unit 503 of the receiving apparatus according to the present invention includes a program association table (PAT) and a program structure table (FAT) in the fast information channel (FIC) data for compatibility with a conventional transmitting apparatus. A function of determining whether there is a new quick information group (FIG) field data composed of analysis information obtained by analyzing a table including a PMT) may be performed.

Accordingly, in order to be compatible with a conventional transmitting apparatus, the receiving apparatus according to the present invention includes analysis information obtained by analyzing a table including a program association table (PAT) and a program structure table (PMT) in the fast information channel (FIC) data. When there is no new fast information group (FIG) field data, the PMI packet is received from the demultiplexer 510 and interpreted to generate an initial object descriptor (IOD), and the initial object descriptor ( An IOD) interpreter may further include a program characteristic information (PSI) interpreter (not shown) for delivering the initial object descriptor (IOD).

The demultiplexer 510 demultiplexes the transport stream TS received from the outer decoding unit 505 by using the transport stream (TS) configuration information received from the fast information channel (FIC) analyzer 503. Then, it is divided into a 14496 section packet and a PES packet and transmitted to the 14496 section analyzer 530 and the elementary stream packet (PES) analyzer 540.

The initial object descriptor (IOD) analyzer 520 generates initial object descriptor (IOD) data using the quick information channel (IOD) configuration information received from the quick information channel (FIC) analyzer 503.

The 14496 section analyzer 530, the elementary stream packet (PES) analyzer 540, and the MPEG-4 audio / video (AV) processor 550 are the 14496 section analyzer 140 described in FIG. 1. Since the stream packet (PES) analyzer 150 and the MPEG-4 audio / video (AV) processor 160 perform the same functions, they will not be described herein again.

6 is a flowchart illustrating a transmission method for reducing an access delay time of a data packet in a digital multimedia broadcasting (DMB) system according to the present invention.

First, program characteristic information (PSI) data of an input stream encoded by MPEG-4 and encapsulated into an MPEG-2 transport stream (TS) is analyzed to calculate a valid data rate and to derive information for configuring an ETI frame (610). ). In particular, analysis information is derived by analyzing a table including a program association table (PAT) and a program structure table (PMT) from the PSI data.

Subsequently, the error tolerance of the input stream, which is encoded by MPEG-4 and then encapsulated into an MPEG-2 transport stream (TS), is enhanced (620).

The transport stream TS having the enhanced error tolerance is stored (630).

ETI frame configuration field values, values for fast information channel (FIC) configuration, and one ETI frame using analysis information obtained by analyzing the table including the derived program association table (PAT) and program structure table (PMT). The amount of transport streams TS necessary to construct is determined (640).

Thereafter, the ETI frame configuration field is configured using the ETI frame configuration field value (650).

In addition, the fast information channel (FIC) is configured using the fast information channel (FIC) configuration information (660). That is, a new quick information group (FIG) field is constructed by using analysis information obtained by analyzing a table including a program association table (PAT) and a program structure table (PMT).

In addition, a transport stream (TS) and a digital audio broadcasting (DAB) stream necessary for configuring one ETI frame are read (670).

Thereafter, the ETI frame configuration field data, the fast information channel (FIC) data, and the transport stream (TS) are multiplexed to complete an ETI frame (680).

Thereafter, the completed ETI frame is converted into a physical form and transmitted (690).

7 is a flowchart illustrating a receiving method for reducing an access delay time of a data packet in a digital multimedia broadcasting (DMB) system according to the present invention.

First, an RF signal is received and demodulated into an IF signal (710), and the IF signal is separated into fast information channel (FIC) data and main service channel (MSC) data (720).

Thereafter, it is determined whether there is new quick information group (FIG) field data having analysis information obtained by analyzing a table including a program association table (PAT) and a program structure table (PMT) from the quick information channel (FIC) data. Service information, information stream (TS) configuration information, and initial object descriptor (IOD) configuration information are derived (730).

Thereafter, only the transport stream TS carrying MPEG-4 audio / video is separated from the main service channel (MSC) data using the service information (740).

The separated transport stream TS is additionally decoded according to the digital multimedia broadcasting (DMB) standard (750).

If the fast information channel (FIC) data includes a fast information group (FIG) field data having analysis information obtained by analyzing a table including a program association table (PAT) and a program structure table (PMT), the channel decoding. A transport stream TS is demultiplexed using the transport stream TS configuration information and separated into 14496 section packets and an elementary stream packet (PES) (760).

Thereafter, initial object descriptor (IOD) data is generated using the derived initial object descriptor (IOD) configuration information (770).

In addition, the separated 14496 section packet is interpreted to generate an MPEG-4 object descriptor (OD) / BIFS sync layer (SL) packet (780).

In addition, the separated elementary stream packet (PES) is interpreted to generate an MPEG-4 audio / video sync layer (SL) packet (790).

Subsequently, the initial object descriptor (IOD) data, the MPEG-4 object descriptor (OD) / BIFS, and the MPEG-4 audio / video sync layer (SL) packet are decoded according to the MPEG-4 standard to generate audio / video. (800).

On the other hand, if there is no fast information group (FIG) field data having analysis information of a table including a program association table (PAT) and a program structure table (PMT) in the quick information channel (FIC) data, The channel-decoded transport stream TS is separated into a program characteristic information (PSI) packet, a 14496 section packet, and an elementary stream packet (PES) (810).

Thereafter, the separated program characteristic information (PSI) packet is interpreted to generate initial object descriptor (IOD) configuration information (820).

Thereafter, initial object descriptor (IOD) data is generated using the initial object descriptor (IOD) configuration information (770).

In addition, the separated 14496 section packet is interpreted to generate an MPEG-4 object descriptor (OD) / BIFS sync layer (SL) packet (780).

In addition, the separated elementary stream packet (PES) is interpreted to generate an MPEG-4 audio / video sync layer (SL) packet (790).

Subsequently, the initial object descriptor (IOD) data, the MPEG-4 object descriptor (OD) / BIFS, and the MPEG-4 audio / video sync layer (SL) packet are decoded according to the MPEG-4 standard to generate audio / video. (800).

In this case, the process in the absence of the FGI field data is an additional element in the present invention.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be apparent to those of ordinary skill in Esau.

As described above, the present invention analyzes table information including a program association table (PAT) and a program structure table (PMT) in advance, and configures a new quick information group (FIG) field to provide fast information which is the fastest access channel. By separately transmitting and receiving the channel FIC, it is possible to shorten the access time of the data packet and to increase the transmission efficiency of the data channel during initial setting and channel change of the receiver.

1 is a configuration diagram of an embodiment of a conventional digital multimedia broadcasting (DMB) receiving apparatus;

2 is a block diagram illustrating an embodiment of a transmission apparatus for shortening an access delay time of a data packet in a digital multimedia broadcasting (DMB) system according to the present invention;

3 is a detailed configuration diagram of an embodiment of a frame structure of a transmitting device for reducing an access delay time of a data packet in a digital multimedia broadcasting (DMB) system according to the present invention;

4 is a diagram illustrating an embodiment of configuring a new quick information group (FIG) field using program association table (PAT) and program structure table (PMT) analysis information;

5 is a configuration diagram of a receiving apparatus for shortening an access delay time of a data packet in a digital multimedia broadcasting (DMB) system according to the present invention;

6 is a flowchart illustrating a transmission method for reducing an access delay time of a data packet in a digital multimedia broadcasting (DMB) system according to the present invention;

7 is a flowchart illustrating a receiving method for reducing an access delay time of a data packet in a digital multimedia broadcasting (DMB) system according to the present invention.

* Explanation of symbols for the main parts of the drawings

100, 500: reception post-processing unit 101, 501: RF receiver

102, 502: channel decoder 103, 503: FIC analysis unit

104, 504: MSC data processing section 105, 505: external decryption section

110: PSI analysis unit 120, 510: demultiplexer

130, 520: IOD analysis section 140, 530: 14496 section analysis section

150, 540: PES analyzer 160, 550: MPEG-4 AV processor

210: transport stream analysis unit 220: external encoder

230: storage unit 240: ETI frame manager

250: ETI frame configuration unit 260: ETI frame transmission unit

310: ETI field component 320: FIC component

330: MSC component 340: Multiplexer

Claims (12)

In the transmitting device for shortening the access delay time of the data packet, Analyzing a table including a program structure table (PMT) and a program association table (PAT) from the program characteristic information (PSI) of the transport stream (TS), the analysis information and frame configuration information to be transmitted through the fast information channel (FIC) Transport stream analyzing means for deriving; External encoding means for reinforcing error tolerance of the transport stream TS; Storage means for storing a transport stream (TS) received from the external calling means; Frame management means for controlling the storage means and managing program structure table (PMT) and program association table (PAT) analysis information and frame configuration information derived from program characteristic information (PSI) received from the transport stream analysis means. ; Frame configuration means for composing a frame using frame configuration information received from the frame management means, a transport stream TS received from the storage means, and a transport stream TS received from the outside; And Frame transmitting means for transmitting the frame received from the frame constructing means Transmission apparatus for shortening the access delay time of a data packet comprising a. The method of claim 1, The frame constituent means, Frame field constructing means for constructing a frame constructing field using the frame constructing information received from the frame managing means; Fast information channel (FIC) constructing means for constructing a fast information group (FIG) field by using configuration information including a program structure table (PMT) and a program association table (PAT) analysis information received from the frame management means; ; A main service channel (MSC) for configuring a main service channel (MSC) using frame configuration information received from the frame management means, a transport stream TS received from the storage means, and a transport stream TS received from the outside; MSC) construction means; And Multiplexing means for multiplexing data received from the frame field configuring means, the fast information channel (FIC) configuring means, and the main service channel (MSC) configuring means; Transmission apparatus for shortening the access delay time of a data packet comprising a. The method of claim 2, The fast information channel (FIC) configuration means, By using the configuration information including the program structure table (PMT) and program association table (PAT) analysis information received from the frame management means, to construct a new quick information group (FIG) field corresponding to each configuration information; And configuring quick information group (FIG) data including the new quick information group (FIG) field and a quick information group (FIG) header. In the transmission method for shortening the access delay time of the data packet, A transport stream analysis step of analyzing a table including a program structure table (PMT) and a program association table (PAT) from the program characteristic information (PSI) to derive analysis information and frame configuration information to be transmitted through a fast information channel (FIC). ; An external encoding step of enhancing error tolerance of the transport stream TS; A frame construction step of constructing a frame using the analysis information, the frame configuration information, a transport stream (TS) with enhanced error tolerance, and a transport stream (TS) received from the outside; And Frame transmission step of transmitting the configured frame Transmission method for shortening the access delay time of a data packet comprising a. The method of claim 4, wherein The frame composition step, A frame field constructing step of constructing a frame construct field using the frame construct information; A quick information channel (FIC) configuration step of constructing a quick information group (FIG) field by using configuration information including the program structure table (PMT) and program association table (PAT) analysis information; A main service channel (MSC) configuration step of configuring a main service channel (MSC) by using the frame configuration information, the transport stream (TS), and a transport stream (TS) received from the outside; And Multiplexing step of multiplexing the configured data Transmission method for shortening the access delay time of a data packet comprising a. The method of claim 5, The fast information channel (FIC) configuration step, Using the configuration information including the program structure table (PMT) and the program association table (PAT) analysis information, a new quick information group (FIG) field corresponding to each configuration information is configured, and the new quick information group ( A fast information group (FIG) data comprising a FIG field and a fast information group (FIG) header. In the receiving device for reducing the access delay time of the data packet, Receiving means for receiving an external RF signal; Channel decoding means for separating the signal received from the receiving means into fast information channel (FIC) data and main service channel (MSC) data; Parsing the fast information group (FIG) field from the fast information channel (FIC) data received from the channel decoding means, and deriving the configuration information including the program association table (PAT) and program structure table (PMT) analysis information. Fast information channel (FIC) analysis means; Primary service channel (MSC) data processing means for separating the information stream TS from the main service channel (MSC) data received from the channel decoding means using the configuration information received from the fast information channel (FIC) analyzing means. ; Outer decoding means for additionally channel decoding the information stream TS received from the main service channel (MSC) data processing means; Demultiplexing means for demultiplexing the information stream TS received from the outer decoding means by using the configuration information received from the fast information channel (FIC) analyzing means; And Post-processing means for analyzing and decoding the configuration information and information stream TS received from the fast information channel (FIC) analyzing means and the demultiplexing means. Receiving apparatus for reducing the access delay time of a data packet comprising a. The method of claim 7, wherein The receiving post-processing means, Initial object descriptor (IOD) interpretation for generating an initial object descriptor (IOD) by receiving configuration information including program association table (PAT) and program structure table (PMT) analysis information from the fast information channel (FIC) analysis means Way; Section analysis means for generating an object descriptor (OD) / BIFS (Binary Format For Scene) sink layer (SL) packet from the packet received from the demultiplexing means; Elementary stream packet (PES) analysis means for generating an audio / video sync layer (SL) packet from the packet received from the demultiplexing means; And Audio / video processing means for decoding packets received from the initial object descriptor (IOD) interpreting means, the section interpreting means, and the elementary stream packet interpreting means Receiving apparatus for reducing the access delay time of a data packet comprising a. The method according to claim 7 or 8, The fast information channel (FIC) analysis means, Interpret the fast information group (FIG) field from the fast information channel (FIC) data received from the channel decoding means, transfer information stream (TS) configuration information to the main service channel (MSC) data processing means, and multiplex information. To the demultiplexing means, and the configuration information including the program association table (PAT) and the program structure table (PMT) analysis information is transmitted to the post-receipt processing means. Receiving device. In the receiving method for reducing the access delay time of the data packet, Receiving a RF signal and separating the fast information channel (FIC) data into primary service channel (MSC) data; A quick information channel (FIC) for deriving configuration information including a program association table (PAT) and a program structure table (PMT) analysis information by analyzing a quick information group (FIG) field from the separated quick information channel (FIC) data. ) Interpretation step; A main service channel (MSC) data processing step of separating an information stream TS from the separated main service channel (MSC) data using the configuration information; An outer decoding step of additionally channel decoding the information stream TS; A demultiplexing step of demultiplexing the outer decoded information stream TS using the configuration information; And Post receive processing step of analyzing and decoding the configuration information and information stream TS Receiving method for reducing the access delay time of a data packet comprising a. The method of claim 10, The post-receipt processing step, An initial object descriptor (IOD) analyzing step of generating initial object descriptor (IOD) data using configuration information including the program association table (PAT) and program structure table (PMT) analysis information; A section analysis step of generating an object descriptor (OD) / binary format for scene (BIFS) sink layer (SL) packet from the demultiplexed packet; An elementary stream packet (PES) analysis step of generating an audio / video sync layer (SL) packet from the demultiplexed packet; And Audio / video processing step of decoding the packets into an audio / video signal Receiving method for reducing the access delay time of a data packet comprising a. The method of claim 10 or 11, The fast information channel (FIC) analysis step, Interpreting the fast information group (FIG) field in the fast information channel (FIC) data and including information stream (TS) configuration information, multiplexing information, and program association table (PAT) and program structure table (PMT) analysis information. Receiving method for reducing the access delay time of the data packet, characterized in that for deriving.