KR101710864B1 - Apparatus for single transmission broadcasting service - Google Patents

Abstract

The present invention discloses an apparatus for a single transmission broadcast service. The apparatus for single transmission service includes an input processor for analyzing input subchannels and outputting subchannel analysis information, extracting and outputting a stream of each subchannel, and an ensemble, a service, a service component, and a subchannel A subchannel stream of the input selected in the output ensemble configuration is configured as a subchannel of the output ensemble using the subchannel analysis information from the input processing unit, and multiplex configuration information (MCI) and service information channel configuration information and subchannel configuration information, and a control unit configured to receive a stream of each subchannel from the input processing unit and to output the subchannel configuration information according to subchannel configuration information and multiplexing configuration information (MCI) received from the multiplexing management unit, A subchannel management section for outputting a subchannel stream necessary for the subchannel management section, An MSC generator for generating a main service channel (MSC) required for each transmission frame by constructing a common interleaved frame (CIF) according to a predetermined setting, An FIC generation unit for generating and outputting a fast information channel (FIC) based on the MCI and SI information received from the multiplexing management unit 203, and an FIC generation unit for generating FIC generated by the FIC generation unit and MSC generated by the MSC generation unit And a DMB modulator configured to receive a transmission frame from the transmission frame generator and generate and transmit a DMB broadcasting signal for a transmission frame.

Description

[0001] APPARATUS FOR SINGLE TRANSMISSION BROADCASTING SERVICE [0002]

The present invention relates to an apparatus for effectively providing a single transmission broadcast service.

There is a single transmission broadcasting service such as a terrestrial DMB-based small-capacity or local broadcasting service. Such a single transmission broadcasting service transmits broadcasting signals to a single transmitter.

In the transmission network of terrestrial DMB broadcasting, an ensemble multiplexer is used to constitute a plurality of services as one ensemble.

1 is a diagram illustrating a transmission network of a conventional terrestrial DMB broadcasting including an ensemble multiplexer.

As shown in FIG. 1, the ensemble multiplexer 30 can receive the service data from the plurality of service encoders 10, 12, 14 through the acquisition network 20. The service encoder includes a video service encoder 10, an audio service encoder 12, and a data service encoder 14. The ensemble multiplexer 30 multiplexes the service data received from the plurality of service encoders 10, 12 and 14 and generates a multiplexed signal according to the ETI (Ensemble Transport Interface) standard. Then, the ensemble multiplexer 30 outputs the terrestrial DMB broadcasting through the distribution network 40 to the COFDM encoder of the transmitter 50.

Here, the ensemble multiplexer 30 is the core of the terrestrial DMB transmission system, and its output, ETI, is a basic interface in the terrestrial DMB transmission network. The ensemble multiplexer 30 is a base layer ensemble that maintains compatibility with terrestrial DMB using a hierarchical modulation technique, It is also used in AT-DMB that transmits enhancement layer ensembles.

ETI is defined as three layers: a logical interface (LI) layer, a network independent (NI) layer, and a network adaptation (NA) layer. The LI layer is a basic logical structure that defines enough information to generate an ensemble. The NI layer is a simple physical interface layer that maps LI and is used as the base interface for ETI-related equipment. The NA layer is a physical interface that is protected against errors so that it can be used in an error-prone network environment compared to NI. This layer also has a structure to be mapped with LI. That is, the LI, which is a core data part, is the same between LI, NI, and NA, and mutual conversion is possible at each layer.

2 shows the structure of an LI frame which is a common part of an ETI. The important data are LIDATA, FC (frame characterization) is a field indicating the characteristics of the frame, STC (stream characterization) is the structure information of the subchannel, MST (main stream data) is the fast information channel (FIC) .

3 is a diagram illustrating a structure of a transmission frame for transmitting an ensemble that is a bundle of terrestrial DMB services. The terrestrial DMB ensemble transmission frame includes a synchronization channel (SC), a fast information channel (FIC), and a main service channel (MSC).

The synchronization channel is a channel for conveying information for decoding on digital communication, and has a predetermined form so as to recognize that the DMB receiver is the beginning of the frame. The fast information channel is a channel for transmitting the actual data to be transmitted to the MSC through a channel in the MSC and information necessary for receiving the terrestrial DMB transmission signal, and includes one or more Fast Information Blocks (FIB) . The main service channel is a channel through which real data such as video data and audio data is transmitted, and is formed of one or more common interleaved frames (CIFs).

In the terrestrial DMB system, in order to provide a transmission mode regardless of the type of data to be transmitted through the high-speed information channel and the main service channel, the configuration and length of the transmission frame vary depending on the transmission mode. Speed information blocks and common interleaved frames as described.

That is, data is transmitted in units of a fast information block (FIB) or a common interleaved frame (CIF) irrespective of the transmission mode. However, only the number of FIB and CIF input according to the transmission mode can be specified. [Table 1] shows an example of the configuration of a transmission frame for each transmission mode of the terrestrial DMB system.

Transfer mode Transmission frame length Number of FIBs per transmission frame Number of CIFs per transmission frame I 96ms 12 4 II 24ms 3 One III 24ms 4 One IV 48ms 6 2

The ETI (Ensemble Transport Interface) is an interface that transmits information for composing an ensemble for terrestrial DMB broadcasting. In case of transmission mode I, as shown in Table 1, one transmission frame is configured every 96ms with four ETI frames, send.

As a result, the multiplexer configures the information necessary for the transmission frame configuration in the main stream data (EST) of the ETI, and the transmitter extracts the FIC field portion from the MTI of the ETI to construct the FIC of the transmission frame, The MSC of the frame is configured.

Therefore, when a broadcasting service is to be performed by a single transmission (one transmitter) such as a terrestrial DMB-based small output and a local broadcasting service, when the multiplexer and the transmitter are located in the same site, And to provide an apparatus for constructing the above-mentioned apparatus.

According to an aspect of the present invention, there is provided an apparatus for a single transmission broadcasting service, the apparatus comprising: an input processor for analyzing input subchannels to output subchannel analysis information, And a subchannel of the input selected in the output ensemble configuration is configured as a subchannel of the output ensemble using the subchannel analysis information from the input processor, and the output ensemble A multiplexing management unit for generating MCI (multiplexing configuration information) and SI (service information) information and subchannel configuration information according to the configuration; a multiplexing unit for receiving a stream of each subchannel from the input processing unit, Information required for the output ensemble configuration according to the multiplexing setting information (MCI) A sub-channel management unit for outputting a null stream; and a sub-channel management unit for configuring a sub-channel stream received from the sub-channel management unit into a common interleaved frame (CIF) according to a predetermined setting, An FIC generation unit for generating and outputting a fast information channel (FIC) based on MCI and SI information received from the multiplex management unit 203, And a DMB receiving unit for receiving a transmission frame from the transmission frame forming unit and generating and transmitting a DMB broadcasting signal for a transmission frame, And a modulation section.

The present invention provides an apparatus for multiplexing an ensemble by receiving input from various service encoders and outputting a broadcasting signal instead of an ETI, and integrating an ensemble multiplexer and a transmitter function in the same manner as an existing ensemble multiplexer. Since the ETI network between the ensemble multiplexer and the transmitter is eliminated, the process of generating the ETI output signal of the multiplexer and the process of processing the ETI input signal of the transmitter are not necessary.

The present invention is equally applicable to a combination of an ensemble multiplexer and a transmitter of an AT-DMB (advanced T-DMB) based on a terrestrial DMB.

1 is a diagram illustrating a transmission network of a conventional terrestrial DMB broadcasting including an ensemble multiplexer.
2 shows the structure of an LI frame which is a common part of an ETI.
3 is a diagram illustrating a structure of a transmission frame for transmitting an ensemble that is a bundle of terrestrial DMB services.
FIG. 4 is a block diagram of an apparatus incorporating a multiplexer and a transmitter according to an embodiment of the present invention.
FIG. 5 is a block diagram of an apparatus incorporating a multiplexer and a transmitter according to another embodiment of the present invention.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. Like reference numerals are used for like elements in describing each drawing.

The terms first, second, A, B, etc. may be used to describe various elements, but the elements should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. And / or < / RTI > includes any combination of a plurality of related listed items or any of a plurality of related listed items.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 4 is a block diagram of an apparatus incorporating a multiplexer and a transmitter according to an embodiment of the present invention.

An apparatus incorporating a multiplexer and a transmitter includes an input processing unit 201, a multiplexing management unit 203, a subchannel management unit 205, an MSC generation unit 207, an FIC generation unit 209, a transmission frame configuration unit 211, and a T And a DMB modulation unit 213.

The input processing unit 201 receives and processes the output of each service encoder in the same manner as a conventional multiplexer. Specifically, the input processing unit 201 analyzes sub-channels of the input, provides sub-channel analysis information to the multiplexing management unit 203, extracts streams of the respective sub-channels, temporarily stores the extracted streams in a buffer, .

The multiplexing management unit 203 performs the function of configuring an ensemble, a service, a service component, and a subchannel in the same manner as a conventional multiplexer, and performs subchannel analysis using the subchannel analysis information provided by the input processing unit 201, The channel stream is configured as a subchannel of the output ensemble. In addition, the multiplexing management unit 203 generates multiplex configuration information (MCI) and service information (SI) information according to the configuration of the ensemble and transmits it to the FIC generation unit 209 in FIG. (MCI) to the sub-channel management unit 205. [

The subchannel management unit 205 receives the stream of each subchannel from the input processing unit 201 and receives the subchannel configuration information and the multiplex setting information MCI from the multiplexing management unit 203. [ The subchannel managing unit 205 delivers the subchannel stream required for the output ensemble configuration to the MSC generating unit 207 according to the subchannel configuration information and the multiplex setting information MCI.

The MSC generator 207 generates a subchannel stream received from the subchannel manager 205 according to a predetermined setting to generate CIFs required for each transmission frame (four CIFs of 96 ms in case of the transmission mode I).

The FIC generation unit 209 receives multiplex configuration information (MCI) and service information (SI) information from the multiplex management unit 203 and generates a fast information channel (FIC) Output.

The transmission frame composing unit 211 composes a transmission frame with the FIC generated by the FIC generation unit 209 and the MSC generated by the MSC generation unit 207, and transmits the frame to the T-DMB modulation unit 213. The T-DMB modulation unit 213 receives the transmission frame from the transmission frame construction unit 211, and generates and transmits a T-DMB broadcasting signal for the transmission frame.

In the conventional multiplexer, when an FIC and a subchannel are configured, they are encoded into an ETI frame to output an ETI signal. However, in the present invention, a transmission frame configuration necessary for transmission is generated without generating and outputting an ETI frame, Signal and outputs it to the AT-DMB as shown in FIG.

FIG. 5 is a block diagram of an apparatus incorporating a multiplexer and a transmitter according to another embodiment of the present invention.

For the AT-DMB, the base layer ensemble and the enhancement layer ensemble are transmitted in a layer-by-layer transmission frame, and the AT-DMB modulation section performs layer modulation to output an AT-DMB signal. For this, the integrated structure proposed in the present invention is extended for each layer as shown in FIG. 5 to form a transport frame for each layer through an FIC generator for each layer, an MSC generator, and a transmission frame generator, , It is possible to integrate the multiplexer and the transmitter for the AT-DMB.

For this, an apparatus that integrates a multiplexer and a transmitter according to another embodiment of the present invention includes an input processor 301, a base layer multiplexing manager 203, an enhancement layer multiplexing manager 313, a subchannel manager 205, A base layer FIC generating unit 309, an enhancement layer FIC generating unit 319, a base layer transmission frame forming unit 311, an enhancement layer transmission frame forming unit 307, an enhancement layer MSC generating unit 317, 321, and an AT-DMB modulation unit 323.

The input processing unit 301 receives and processes the output of each service encoder. Specifically, the input processing unit 301 analyzes the input sub-channels and provides the sub-channel analysis information to the base layer multiplexing management unit 303 and the enhancement layer multiplexing management unit 313. [ The input processing unit 301 extracts the streams of the respective subchannels, temporarily stores them in a buffer, and transmits them to the subchannel management unit 305. [

The base layer multiplexing management unit 303 functions as a base layer ensemble, a service, a service component, and a subchannel. The enhancement layer multiplexing management unit 313 performs functions to configure an enhancement layer ensemble, a service, a service component and a subchannel.

The base layer multiplexing management unit 303 and the enhancement layer multiplexing management unit 313 use the sub-channel analysis information provided by the input processing unit 301 to generate an output base layer ensemble configuration and a sub-channel stream of the input selected in the enhancement layer ensemble configuration. To the output base layer and the subchannels of the enhancement layer ensemble, respectively. In addition, the base layer multiplexing management unit 303 and the enhancement layer multiplexing management unit 313 are configured to multiplex the base layer MCI (multiplex configuration information), the enhancement layer MCI, and the base layer SI (service information) according to the configuration of the base layer and the enhancement layer ensemble, And enhancement layer SI information to the base layer FIC generation unit 309 and the enhancement layer FIC generation unit 319, respectively, and transmits base layer and enhancement layer subchannel configuration information, base layer and enhancement layer multiplex setup information MCI To the sub-channel management unit 305. The sub-

The subchannel management unit 305 receives the streams of the respective subchannels from the input processing unit 201 and receives the base layer and enhancement layer subchannel configuration information and the base layer information from the base layer multiplexing management unit 303 and the enhancement layer multiplexing management unit 313. [ And enhancement layer multiplexing setting information MCI. The subchannel management unit 305 generates a subchannel stream required for the output base layer and the enhancement layer ensemble configuration according to the base layer and enhancement layer subchannel configuration information and the base layer and the enhancement layer multiplexing configuration information (MCI) 307 and the enhancement layer MSC generator 317, respectively.

The base layer MSC generator 307 constructs a subchannel stream received from the subchannel manager 305 according to a predetermined base layer configuration to generate a CIF required for each transmission frame. The enhancement layer MSC generator 317 constructs a subchannel stream received from the subchannel manager 305 according to a predetermined enhancement layer configuration to generate an MSC required for each transport frame.

The base layer FIC generation unit 309 receives base layer MCI and SI information from the base layer multiplexing management unit 303 and generates a base layer fast information channel (FIC) . The enhancement layer FIC generation unit 319 receives the enhancement layer MCI and SI information from the enhancement layer multiplexing management unit 313 and generates an enhancement layer FIC (fast information channel) .

The base layer transmission frame constructing unit 311 constructs a transmission frame with the FIC generated by the base layer FIC generating unit 309 and the MSC generated by the base layer MSC generating unit 307 and transmits the frame to the AT-DMB modulating unit 323 . The enhancement layer transmission frame constructing unit 321 constructs a transmission frame from the FIC generated by the enhancement layer FIC generating unit 319 and the MSC generated by the enhancement layer MSC generating unit 317 and transmits the frame to the AT- .

The AT-DMB modulator 323 receives the transmission frame from the base layer transmission frame composer 311 and the enhancement layer transmission frame composer 321, and generates and transmits an AT-DMB broadcasting signal for the transmission frame .

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the present invention as defined by the following claims It can be understood that

201: input processor
203: multiplexing management unit
205: Subchannel manager
207: MSC generating unit
209: FIC generation unit
211: Transmission frame constituent unit
213: T-DMB modulation section

Claims (12)

A single transmission broadcast service method performed in a broadcast service apparatus for a single transmission broadcast service,
Analyzing a plurality of service information received from a plurality of service encoders to obtain subchannel analysis information;
Extracting a stream of each subchannel from the subchannel analysis information, and extracting multiplex configuration information (MCI) information, service information (SI) information, and multiplexing information based on a subchannel stream output from the broadcasting service apparatus among the streams of the respective subchannels, Generating sub-channel configuration information;
Generating information on a subchannel of an output ensemble based on the MCI information, SI information, and subchannel configuration information;
Generating a transmission frame including information on a subchannel of the output ensemble; And
And generating and outputting a broadcast service signal using information on an output ensemble subchannel included in the transmission frame. delete The method according to claim 1,
Wherein generating the information for the output ensemble subchannel comprises:
Generating the MCI information, the SI information, and the subchannel configuration information based on the subchannel stream output from the broadcasting service apparatus from the subchannel analysis information;
Generating main service channel (MSC) information based on the MCI information and subchannel configuration information;
Generating fast information channel (FIC) information based on the MCI information and SI information; And
And generating information on the output ensemble subchannel using the MSC information and the FIC information. The method of claim 3,
The MSC information,
Wherein the information is generated based on CIF (common interleaved frame) information set in advance according to a frame transmitted from the broadcast service apparatus. The method according to claim 1,
Wherein generating the information for the output ensemble subchannel comprises:
Generating first ensemble information and second ensemble information that are performed in different layers from the sub-channel analysis information; And
And generating information on the output ensemble subchannel based on the first ensemble information and the second ensemble information. The method of claim 5,
Wherein the generating of the first ensemble information and the second ensemble information comprises:
Second MC information, first SI information, second SI information, first subchannel configuration information, and second subchannel configuration information based on the subchannel stream output from the broadcast service apparatus from the subchannel analysis information, Generating configuration information;
Generating first MSC information based on the first MCI information and first subchannel configuration information, generating first FIC information based on the first MCI information and first SI information,
Generating second MSC information based on the second MCI information and second subchannel configuration information, generating second FIC information based on the second MCI information and the second SI information, And
Generating first ensemble information using the first MSC information and the first FIC information and generating second ensemble information using the second MSC information and the second FIC information, / RTI > A single transmit broadcast service apparatus performing a single transmit broadcast service method,
The method of claim 1, further comprising: analyzing a plurality of service information received from a plurality of service encoders to obtain subchannel analysis information; extracting a stream of each subchannel from the subchannel analysis information; (MCI) information, SI (service information) information and subchannel configuration information based on a subchannel stream outputted from the apparatus and generates subchannel configuration information based on the MCI information, SI information and subchannel configuration information, Generates a transmission frame including information on a subchannel of the output ensemble, generates a broadcasting service signal using information on an output ensemble subchannel included in the transmission frame, and outputs the broadcasting service signal ; And
And a storage unit for storing information processed and processed by the processing unit. delete The method of claim 7,
Wherein,
Generates SI information and subchannel configuration information based on the subchannel stream outputted from the single transmission broadcasting service apparatus from the subchannel analysis information, and generates MCI information, SI information and subchannel configuration information based on the MCI information and subchannel configuration information, service channel information, generates fast information channel (FIC) information based on the MCI information and the SI information, and generates information on the output ensemble subchannel using the MSC information and the FIC information Wherein the single transmission broadcasting service device is a single transmission broadcasting service device. The method of claim 9,
The MSC information,
Wherein the information is generated based on CIF (common interleaved frame) information set in advance according to a frame transmitted from the single transmission broadcasting service apparatus. The method of claim 7,
Wherein,
Generates first ensemble information and second ensemble information that are performed in different layers from the subchannel analysis information, and generates information on the output ensemble subchannel based on the first ensemble information and the second ensemble information And a transmission unit for transmitting the service information. The method of claim 11,
Wherein,
Second MC information, first SI information, second SI information, first subchannel configuration information, and second subchannel configuration information based on the subchannel stream outputted from the single transmission broadcasting service apparatus from the subchannel analysis information, Generates subchannel configuration information, generates first MSC information based on the first MCI information and first subchannel configuration information, and generates first FIC information based on the first MCI information and the first SI information Generates second MSC information based on the second MCI information and second subchannel configuration information, generates second FIC information based on the second MCI information and the second SI information, And generates first ensemble information using the first FIC information and second ensemble information using the second MSC information and the second FIC information.

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