JP2009278589A - System for digital broadcast and method of digital broadcast - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a system for digital broadcast and a method of digital broadcast capable of properly receiving superimposed data in an auxiliary channel of the received hierarchy even if at least a part of the hierarchy only is received in digital broadcast. <P>SOLUTION: Data of the auxiliary channel are generated for each hierarchy. Data of an auxiliary channel for an A hierarchy are superimposed on an AC carrier of the A hierarchy and that of an auxiliary channel for a B hierarchy is superimposed on an AC carrier of the B hierarchy. Even in such a case that the partial reception of the A hierarchy only is made, such a situation can be avoided that auxiliary channel data superimposed on the AC carrier cannot be used in an event of partial reception as in a conventional case, because data superimposed on the AC carrier of the A hierarchy are for the A hierarchy. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a digital broadcasting system and a digital broadcasting method, and more particularly to an auxiliary channel in digital broadcasting.

  Terrestrial digital broadcasting has been started as an alternative to analog terrestrial broadcasting. In this terrestrial digital broadcasting, the transmission band of one channel is divided into 13 bands (OFDM segments). The OFDM segment is a basic band signal (1/13 of the TV channel band) of a transmission signal in which a control signal carrier is added to a data carrier. In the transmission band of one channel divided into 13 segments, transmission parameters and information to be transmitted can be set for each segment.

  For this reason, it is possible to broadcast a high-definition television broadcast on one channel, or to broadcast various services such as a plurality of standard television broadcasts and data broadcasts on one channel.

  Also, by setting the transmission parameters of some segments to be resistant to interference, in addition to fixed reception at home, it is suitable for reception by mobile objects such as automobiles and reception by mobile terminals (hereinafter referred to as partial reception). In terrestrial digital broadcasting, mobile broadcasting service (partial reception) is performed on one central segment of 13 segments.

  Further, in digital broadcasting, there is a channel called an auxiliary channel (hereinafter referred to as AC) for transmitting additional information, and the additional information of this channel is distributed and superimposed on the AC carrier of each segment.

Patent Document 1 discloses a technique for superimposing control information of a base station or the like on such an AC and using it for control of the base station.
JP 2005-191904 A

  However, since the additional information described above is distributed and superimposed on the AC carrier of each segment, AC additional information cannot be normally received unless signals of all layers are received. For example, when only layer A (partial reception layer) is received, data transmitted by AC cannot be normally received.

  Therefore, the present invention has been invented in view of the above-mentioned problems, and its purpose is to receive only at least a part of layers (for example, layer A (partial reception layer)) in digital broadcasting. Another object of the present invention is to provide a digital broadcasting system and a digital broadcasting method that can correctly receive data superimposed on the auxiliary channel of the received hierarchy.

  The present invention for solving the above-mentioned problems is a digital broadcasting system, characterized by comprising superimposing means for superimposing auxiliary channel data in the digital broadcasting generated for each layer on the auxiliary channel carrier of the corresponding layer. .

  The present invention for solving the above-mentioned problems is a digital broadcasting method, wherein data to be superimposed on auxiliary channels in digital broadcasting is generated for each layer, and the data of each layer is superimposed on the carrier of the auxiliary channel of the corresponding layer. It is characterized by.

  In the present invention, data to be superimposed on the auxiliary channel in the digital broadcasting is generated for each layer, and the data of each layer is configured to be superimposed on the carrier of the auxiliary channel of each layer. , Even when only layer A (partial reception layer) is received, data superimposed on the auxiliary channel of the received layer can be correctly received.

  An embodiment of the present invention will be described. In the following description, it is assumed that one channel is composed of two layers of layer A (partial reception layer) and layer B (fixed reception layer).

  In the embodiment of the present invention, the data to be superimposed on the auxiliary channel is generated so as to be completed for each layer. That is, the auxiliary channel data of each layer has a data amount that can be superimposed on the AC carrier of that layer. Then, the data of the auxiliary channel of each layer is superimposed on the AC carrier of the corresponding layer.

  FIG. 1 shows a state in which the data for the A layer is superimposed on the AC carrier of the A layer and the data for the B layer is superimposed on the AC carrier of the B layer among the auxiliary channel data.

  Here, the broadcast wave shown in FIG. 1 in which the data of the auxiliary channel for the A layer is superimposed on the AC carrier of the A layer and the data of the auxiliary channel for the B layer is superimposed on the AC carrier of the B layer is converted into the A layer. Only partial reception is performed. In this case, only the data superimposed on the AC carrier of the A layer can be acquired. However, in the present embodiment, the data superimposed on the AC carrier of the A layer is data for the A layer, so that In the case of partial reception, the auxiliary channel data superimposed on the AC carrier cannot be used.

  Here, the data to be superimposed on the auxiliary channel includes, for example, (N-1) on-air audio data for generating audio. On-air audio is generated with a data amount that can be superimposed on the AC carrier of the A layer, and is generated only in the A layer. Then, this is superimposed on the AC carrier of the A layer. At present, when N-1 audio is generated at a relay site, analog broadcast audio is often used. This is because digital broadcast audio is delayed by more than 2 seconds due to time interleaving processing, encoding, and decoding. However, by transmitting on-air audio with a low-delay AC signal, (N-1) audio can be realized without delay at the relay site, and reception of broadcast waves is sufficient for reception of only the A layer. This method is effective when analog broadcasting stops in the future. Note that the (N-1) voice is a voice obtained by subtracting one's voice from the on-air voice because it is difficult to talk when the words spoken by the relay destination are sent back in the case of relaying or the like.

  In addition, there is a control signal for the super device of the relay station that can receive the digital broadcast wave of the master station, which is data to be superimposed on the auxiliary channel. This is generated so as to be completed only in the A layer, and this is superimposed on the carrier of the auxiliary channel in the A layer.

  Moreover, although it is the data superimposed on an auxiliary channel, there is control information for partial reception. For example, control information unique to one segment (partial reception) is generated so as to be completed only in the A layer, and this is superimposed on the carrier of the auxiliary channel in the A layer.

  In addition, although the data is superimposed on the auxiliary channel, the data superimposed on the AC carrier of the A layer is AAC (Advanced Audio Coding) data, and the data superimposed on the AC carrier of the B layer is SBR (Spectral Band Replication) data. . SBR is a technology additionally defined by MPEG as an optional tool of the AAC system, and can provide high-quality audio by adding SBR data that complements AAC data. Therefore, even a receiver that can receive only the A layer can reproduce the sound based on the AAC data. Further, if the receiver can receive both the A layer and the B layer, the AAC data and the SBR data can be used. By using it, high-quality sound can be reproduced.

  Further, there is marathon relay data as data to be superimposed on the auxiliary channel. For example, by using the data for the A layer as the distance information of the runner and the data for the B layer as the position information such as the longitude and latitude of the runner and the altitude information, even a receiver that can receive only the A layer is a runner. If the receiver is able to know the distance traveled by the vehicle and can receive both the A layer and the B layer, more detailed position information of the runner can be acquired.

  As described above, the data example superimposed on the auxiliary channel has been described, but the present invention is not limited to this. That is, the data amount is an amount that can be superimposed on the AC carrier of each hierarchy, and the content of the data is not limited as long as the data is completed for each hierarchy.

  In the above description, the hierarchies are described as the A hierarchy (partial reception hierarchy) and the B hierarchy (fixed reception hierarchy), but the present invention is not limited to this. For example, the hierarchies may be three hierarchies of A hierarchy, B hierarchy, and C hierarchy.

  Next, a specific example of the broadcasting system in the embodiment of the present invention will be described.

  FIG. 2 is a block diagram of the broadcasting system in the embodiment of the present invention.

  The broadcasting system according to the present embodiment is composed of a TS remultiplexing unit 10 that remultiplexes TS, an OFDM modulation unit 11, and an AC encoder 12.

  The TS re-multiplexing unit 10 multiplexes a plurality of MPEG-2 transport streams in which video, audio, data, and the like are multiplexed, and a transport stream that conforms to an ISDB-T transmission method that enables hierarchical transmission by a segment structure (Broadcast TS) is generated.

  The AC encoder 12 encodes AC data for layer A (for example, AAC data for audio data) generated for each layer and AC data for layer B (for example, SBR data for audio data).

  The OFDM modulation unit 11 performs OFDM modulation on the broadcast TS, encoded AC data, and the like. As shown in FIG. 3, the OFDM modulation unit 11 includes a hierarchical modulation processing unit 20 and a carrier modulation unit 21.

  The hierarchical modulation processing unit 20 performs modulation processing of each layer such as error correction, carrier modulation, layer synthesis, and interleaving on the broadcast TS.

  The carrier modulation unit 21 superimposes the AC data for the A layer on a predetermined carrier of the A layer, and superimposes the AC data for the B layer on a predetermined carrier of the B layer. In addition, TMCC, pilot signals, and the like are also superimposed on a predetermined carrier.

  Then, the output signal of the hierarchical modulation processing unit 20 and the output signal of the carrier modulation unit 21 are combined and output as a broadcast wave.

  Next, another broadcasting system of the present embodiment will be described.

  FIG. 4 is a block diagram showing another broadcasting system of the present embodiment.

  As shown in FIG. 4, an AC inserter 30 is provided between the TS remultiplexing unit 10 and the OFDM modulation unit 11. The AC inserter 30 inserts AC data created for each hierarchy into the AC. At this time, whether the AC data created for each hierarchy is added with identification information for identifying the hierarchy for each data, or is the AC data of any hierarchy from the input terminal of the AC inserter 30. Can be identified.

  Here, the AC data insertion method of the AC inserter 30 is inserted into the dummy byte portion of each TS packet. At this time, in the AC data hierarchy separating unit 41 described later, identification information for identifying the hierarchy is inserted together with the data in order to identify the hierarchy of the AC data. If the AC data layer separation unit 41 can identify the layer corresponding to the packet from the PID or the like of the packet in which the AC data is inserted in the dummy byte portion, the identification information for identifying the layer is always included with the data. There is no need to insert.

  The OFDM modulation unit 11 performs OFDM modulation on the superimposed TS on which the AC data created for each layer is superimposed to obtain an OFDM signal. As shown in FIG. 5, the OFDM modulation unit 11 separates the AC data for each layer separately from the layer modulation processing unit 40 that performs the modulation processing of the TS of each layer and the modulation processing of the TS of each layer. An AC data layer separation unit 41 and a carrier modulation unit 42 that superimposes the separated AC data for each layer on the AC carrier of each layer are provided.

  As described above, the AC data layer separation unit 41 separates the AC data inserted in the dummy byte portion of each TS packet into each layer based on identification information for identifying the layer, or PID of the packet, The AC data is output to the carrier modulation unit 42.

  The carrier modulation unit 42 superimposes the AC data output from the AC data layer separation unit 41 on the AC carrier of the corresponding layer.

  In this way, the output signal of the hierarchical modulation processing unit 40 and the output signal of the carrier modulation unit 42 are combined to output a broadcast wave (OFDM signal).

  Furthermore, another broadcasting system will be described.

  In the present broadcasting system, an example in which AC data is multiplexed on an invalid hierarchy will be described.

  As shown in FIG. 6, this broadcasting system includes a TS remultiplexing unit 50 that remultiplexes TSs and an OFDM modulation unit 51.

  The AC data TS of each layer is input to the TS remultiplexing unit 50 together with other video and audio TSs. The TS re-multiplexing unit 50 multiplexes a plurality of MPEG-2 transport streams in which video, audio, data, and the like are multiplexed, and a transport stream that conforms to an ISDB-T transmission method capable of hierarchical transmission using a segment structure. (Broadcast TS) is generated, and layer data information of the TS packet is set to “0100”, and AC data is stored in the data portion. At this time, in order to identify the hierarchy of the AC data, identification information for identifying the hierarchy of the AC data is also stored together with the AC data. Further, the layer of AC data may be identified by the information of Layer indicator. In this case, any one of “1001” to “1111” of the layer indicator is used. For example, if the layer indicator is “1001”, it can be identified as AC data of the A layer (details are ARIB (See STD-B31).

  The OFDM modulation unit 51 performs OFDM modulation on the broadcast TS output from the TS remultiplexing unit 50 to obtain an OFDM signal. As shown in FIG. 7, the OFDM modulation unit 51 separates the hierarchical modulation processing unit 60 that performs the modulation processing of the TS of each layer and the AC of identifying the AC data TS from the broadcast TS separately from the modulation processing of the TS of each layer. A data separation unit 61 and a carrier modulation unit 62 that extracts AC data from a TS packet of AC data output from the AC data separation unit 61 and superimposes the AC data on an AC carrier in a corresponding layer. In addition, the identification of the hierarchy of AC data in the carrier modulation part 62 is performed by the identification information of the hierarchy inserted with AC data, and the information of Layer indicator as mentioned above. Then, the output signal of the hierarchical modulation processing unit 60 and the output signal of the carrier modulation unit 62 are combined to output a broadcast wave (OFDM signal).

  In the above-described embodiment, the example of the two hierarchies of the A hierarchy and the B hierarchy has been described. However, the present invention is not limited to this. For example, there may be three hierarchies of A hierarchy, B hierarchy, and C hierarchy.

FIG. 1 is a diagram for explaining the present invention. FIG. 2 is a block diagram of the broadcasting system in the embodiment. FIG. 3 is a block diagram of the broadcasting system in the embodiment. FIG. 4 is a block diagram of another broadcasting system in the embodiment. FIG. 5 is a block diagram of another broadcasting system in the embodiment. FIG. 6 is a block diagram of another broadcasting system in the embodiment. FIG. 7 is a block diagram of another broadcasting system in the embodiment.

Explanation of symbols

10, 50 TS remultiplexing unit 11, 51 OFDM modulation unit 12 AC encoder 20, 40, 60 Hierarchical modulation processing unit 21, 42, 62 Carrier modulation unit 30 AC inserter 41 AC data layer separation unit 61 AC data separation unit

Claims (12)

A digital broadcasting system,
A digital broadcasting system comprising superimposing means for superimposing auxiliary channel data in digital broadcasting generated for each layer on the auxiliary channel carrier of the corresponding layer.   The digital broadcasting system according to claim 1, wherein the superimposing unit superimposes audio data of on-air audio on a carrier of an auxiliary channel of A layer.   The digital broadcasting system according to claim 1, wherein the superimposing unit superimposes the control information of the relay station on the carrier of the auxiliary channel of the A layer.   The digital broadcasting system according to claim 1, wherein the superimposing unit superimposes control information for A layer on a carrier of an auxiliary channel of A layer.   2. The digital broadcasting system according to claim 1, wherein the superimposing unit superimposes AAC data on a carrier of an A-channel auxiliary channel and superimposes SBR data on a carrier of a B-layer auxiliary channel.   2. The digital according to claim 1, wherein the superimposing unit superimposes distance information of an object on a carrier of an auxiliary channel of the A layer and superimposes position information of the object on a carrier of an auxiliary channel of the B layer. Broadcast system. A digital broadcasting method,
Generate data to be superimposed on auxiliary channels in digital broadcasting by layer,
A digital broadcasting method, wherein the data of each layer is superimposed on a carrier of an auxiliary channel of a corresponding layer.   8. The digital broadcasting method according to claim 7, wherein audio data of on-air audio is superimposed on a carrier of an A channel auxiliary channel.   8. The digital broadcasting method according to claim 7, wherein the control information of the relay station is superimposed on the carrier of the auxiliary channel of the A layer.   8. The digital broadcasting method according to claim 7, wherein control information for A layer is superimposed on a carrier of an auxiliary channel of A layer.   8. The digital broadcasting method according to claim 7, wherein AAC data is superimposed on a carrier of an A channel auxiliary channel, and SBR data is superimposed on a carrier of an auxiliary channel of B layer.   8. The digital broadcasting method according to claim 7, wherein the distance information of the object is superimposed on the carrier of the auxiliary channel of the A layer, and the position information of the object is superimposed on the carrier of the auxiliary channel of the B layer.

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