JP5350869B2 - Transmission system and method, multiplexing apparatus, reconstruction apparatus, and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a transmission system and method which can use the broadcasting TS effectively, and to provide a multiplexer and a reconfiguration device. <P>SOLUTION: The transmission system for transmitting at least one broadcasting TS through multiplexing with at least one other broadcasting TS includes a multiplexing means for changing the partial information of the dummy bite section of a TS packet in a predetermined broadcasting TS excepting the null packet into the identification information for identifying the TS packet of the predetermined broadcasting TS, and changing the information of the other dummy bite section into the information of the dummy bite section of other broadcasting TS with which the broadcasting TS is multiplexed, and then multiplexing the TS packet of the predetermined broadcasting TS which has changed the information of the dummy bite section in place of the null packet of the other broadcasting TS, and a reconfiguration means for extracting the TS packet of the predetermined broadcasting TS from the broadcasting TS with which a predetermined broadcasting TS is multiplexed based on the identification information of the dummy bite section, and reconfiguring the predetermined broadcasting TS by restoring the dummy bite section of the extracted TS packet. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a transmission system and method, a multiplexing device, a reconstruction device, and a program.

  Recently, the operation of terrestrial digital broadcasting has been started. In the relay transmission in the terrestrial digital broadcasting, unlike the conventional analog broadcasting, as disclosed in Patent Document 1, the broadcast wave is not used but the STL (microwave line, optical line, etc.) is used. Multi-stage relaying is performed using Studio to Transmitter Link (TTL) or TTL (Transmitter to Transmitter Link).

  Under such circumstances, it is preferable to construct a protection line such as TTL for operational safety.

Japanese Patent Laid-Open No. 2004-165753

  When constructing a protection line, it is necessary to construct several TTL systems in addition to the currently used system.

  However, in order to construct a new TTL system, it is necessary to secure a new frequency, but it is difficult to secure a new frequency.

  In addition, a TTL transmission / reception device for the additional standby system is required, which leads to an increase in cost. For example, when an optical line is prepared for the standby line, the cost is increased. It was limited to.

  Further, even if the TTL system is duplicated, there is a problem that the line is disconnected when frequency selective interference occurs in the frequency used.

  On the other hand, the transmission rate of broadcast TS currently in operation is about 32.5 Mbps, but the actual transmission rate is about 18.7 Mbps (current parameter operation). In order to maintain the transmission rate, the transmission rate at which unused areas (NULL) that are not actually used are transmitted is about 12.7 M (188 byte value). Therefore, it is not always preferable from the viewpoint of effective use of the line.

  Therefore, the present invention has been invented in view of the above problems, and an object of the present invention is to provide a transmission system and method, a multiplexing apparatus, a reconstruction apparatus, and a program that can effectively use a broadcast TS. .

  The present invention for solving the above problems is a transmission system that multiplexes and transmits at least one broadcast TS (Transport Stream) to at least one other broadcast TS, and transmits a null packet of a predetermined broadcast TS. The information of a part of the dummy byte part of the removed TS packet is changed to identification information for identifying the TS packet of the predetermined broadcast TS, and the information on the other dummy byte part is multiplexed with the broadcast TS. Changing to the information of the dummy byte part of the other broadcast TS, in place of the null packet of the other broadcast TS, multiplexing means for multiplexing the TS packet of the predetermined broadcast TS in which the information of the dummy byte part is changed, Based on the identification information of the dummy byte part, the TS packet of the predetermined broadcast TS is obtained from the broadcast TS in which the predetermined broadcast TS is multiplexed. Out, to restore the dummy byte portion of the extracted TS packet, a transmission system and having a reconstructing means for reconstructing said predetermined broadcast TS.

  The present invention for solving the above-described problems is a multiplexing apparatus that multiplexes at least one broadcast TS (Transport Stream) into at least one other broadcast TS, and removes a null packet from a predetermined broadcast TS. In addition to changing part of the information in the dummy byte part of the TS packet to identification information for identifying that it is a TS packet of the predetermined broadcast TS, the information in the other dummy byte part is multiplexed with the broadcast TS. And a multiplexing means for multiplexing the TS packet of a predetermined broadcast TS in which the information of the dummy byte part is changed instead of the null packet of the other broadcast TS. Is a multiplexing device characterized by the following.

  The present invention that solves the above-mentioned problem is changed to identification information for identifying that a part of information of a dummy byte portion of a TS packet excluding a null packet in a predetermined broadcast TS is a TS packet of the predetermined broadcast TS A reconstruction device that receives the broadcast TS in which the TS packet is multiplexed and reconstructs the predetermined broadcast TS from the broadcast TS, based on the identification information of the dummy byte portion. Reconstructing means for extracting a TS packet of the predetermined broadcast TS from the broadcast TS multiplexed with the broadcast TS, restoring a dummy byte portion of the extracted TS packet, and reconstructing the predetermined broadcast TS This is a reconstruction device characterized by that.

  The present invention for solving the above-described problems is a transmission method for transmitting at least one broadcast TS (Transport Stream) by multiplexing it with at least one other broadcast TS, and the transmission side is configured to transmit a predetermined broadcast TS. Among them, the information of a part of the dummy byte part of the TS packet excluding the null packet is changed to identification information for identifying the TS packet of the predetermined broadcast TS, and the information of the other dummy byte part is changed to the broadcast Change to the information of the dummy byte part of the other broadcast TS that multiplexes the TS, multiplex the TS packet of the predetermined broadcast TS in which the information of the dummy byte part is changed instead of the null packet of the other broadcast TS, Based on the identification information of the dummy byte part, the receiving side transmits a TS packet of the predetermined broadcast TS from the broadcast TS in which the predetermined broadcast TS is multiplexed. Extracted, to restore the dummy byte portion of the extracted TS packet is a transmission method characterized in that reconstructing the predetermined broadcast TS.

  The present invention for solving the above-described problem is a program for a multiplexing apparatus that multiplexes at least one or more broadcast TS (Transport Stream) into at least one or more other broadcast TSs. The information of a part of the dummy byte part of the TS packet excluding is changed to identification information for identifying the TS packet of the predetermined broadcast TS, and the information of the other dummy byte part is multiplexed with the broadcast TS. A process of changing to information of a dummy byte part of another broadcast TS, and a process of multiplexing a TS packet of a predetermined broadcast TS in which the information of the dummy byte part is changed instead of the null packet of the other broadcast TS Is a program that causes a multiplexing device to execute.

  The present invention that solves the above-mentioned problem is changed to identification information for identifying that a part of information of a dummy byte portion of a TS packet excluding a null packet in a predetermined broadcast TS is a TS packet of the predetermined broadcast TS A program of a reconstruction device that receives the broadcast TS in which the TS packet is multiplexed and reconstructs the predetermined broadcast TS from the broadcast TS, and based on the identification information of the dummy byte part, A process of extracting a TS packet of the predetermined broadcast TS from the broadcast TS multiplexed with the predetermined broadcast TS, and a process of restoring the dummy byte part of the extracted TS packet and reconstructing the predetermined broadcast TS Is a program that causes the reconstruction device to execute.

  According to the present invention, it is possible to effectively use a frequency for transmitting a broadcast TS by effectively utilizing an unused area of the broadcast TS.

FIG. 1 is a diagram showing a format structure of a broadcast TS packet. FIG. 2 is a diagram for explaining the present invention. FIG. 3 is a diagram showing the configuration of the first embodiment. FIG. 4 is a block diagram of the multiplexing apparatus 1. FIG. 5 is an operation flowchart of the multiplexing apparatus 1. FIG. 6 is a block diagram of the reconstruction device 2. FIG. 7 is an operation flowchart of the reconstruction device 2. FIG. 8 is a diagram illustrating the configuration of the second embodiment. FIG. 9 is a block diagram of the relay device 10 according to the second embodiment. FIG. 10 is an operation flowchart of the relay device 10 according to the second embodiment. FIG. 11 is a block diagram of the reconstruction device 2 of the relay device 10 according to the second embodiment. FIG. 12 is an operation flowchart of the reconstruction device 2 according to the second embodiment. FIG. 13 is a block diagram of the relay device 10 according to the third embodiment.

  A broadcast TS multiplexing method according to the present invention will be described.

  First, the current broadcast TS packet will be described. FIG. 1 shows the format structure of a broadcast TS packet. The broadcast TS packet (204 bytes) is composed of a program data storage area (188 bytes), a dummy byte storage area (8 bytes) for storing TMCC (Transmission and Multiplexing Configuration Control), and a parity storage area (8 bytes). Is done.

  Next, in the broadcast TS as shown in FIG. 1, consider a case where the broadcast TS2 is multiplexed with the broadcast TS1 by the multiplexing device 1 as shown in FIG.

  In the broadcast TS1, a packet without actual data called a Null packet is inserted in order to keep the transmission rate constant. Therefore, when the broadcast TS2 is multiplexed with the broadcast TS1, a broadcast TS packet other than the Null packet of the broadcast TS2 is multiplexed instead of the Null packet.

  However, simply by multiplexing TS packets other than the Null packet of the broadcast TS2 instead of the Null packet of the broadcast TS1, the broadcast TS1 does not become normal and cannot be transmitted correctly.

  Therefore, the basic information in the dummy byte part storage area of the TS packet of the broadcast TS2 is replaced with information for the broadcast TS1.

  Here, among the basic information of the dummy byte part storage area, TMCC identification, emergency broadcast activation control, change instruction, frame head flag, frame synchronization identification, transmission parameter switching index are IIP (ISDB-T Information Packet of broadcast TS2). ) Can be obtained from the MCCI data in FIG. In addition, the buffer reset flag is fixed to 0 in digital terrestrial broadcasting, so there is no problem.

  However, since identification information and layer information indicating that it is a TS packet of the broadcast TS2 are required, the TS packet is a TS packet of the broadcast TS2 and its layer is identified using the Layer_indicator of the dummy byte part storage area. Add identification information. Specifically, Layer_indicator is an identifier (0100 to 0111 or 1001 to 1111) for identifying that the provider is a TS packet that multiplexes unique data, and Layer_indicator of the TS packet of broadcast TS2 to be multiplexed is broadcast TS2. The identifier is changed to one prepared for use (0100 to 0111 or 1001 to 1111). Note that the operator-specific data is adjusted with other operators so as not to overlap with the added hierarchy information.

  For TSP_counter, the value of TSP_counter of the TS packet of the broadcast TS2 to be multiplexed may be assigned as it is. By doing so, even when the broadcast TS2 is multiplexed with a plurality of broadcast TSs when the broadcast TS2 is reconstructed, the TS packet order of the broadcast TS2 can be understood when the broadcast TS2 is reconstructed. .

  As for AC_data_effective_bytes of broadcast TS2, 2 bytes out of 4 bytes are used for identification with broadcast TS1 and broadcast TS2. Specifically, 00 is AC data of broadcast TS1, 1 byte is used, 01 is AC data of broadcast TS1, 2 bytes are used, 10 is AC data of broadcast TS2, 1 byte is used, 11 is AC data of broadcast TS2, and 2 bytes are used. Identify as in use.

  In this way, the TS packet of the broadcast TS2 whose information in the dummy byte part storage area is changed is multiplexed with the broadcast TS1 instead of the Null packet of the broadcast TS1.

  Next, the case where the reconstruction device 2 reconstructs the broadcast TS2 from the broadcast TS1 will be described.

  First, the TS packet of the broadcast TS2 is extracted from the broadcast TS1 with reference to the Layer_indicator of the dummy byte part of the TS packet of the broadcast TS1. In addition, when multiplexing to one broadcast TS, if TS packets of the broadcast TS2 are arranged in the order of extraction, packets excluding NULL packets are arranged in order. However, when multiplexing to a plurality of broadcast TSs, the order of TS packets is not known, so as described above, TS packets of the extracted broadcast TS2 are arranged using TSP_counter.

  Also, MCCI data is extracted from the broadcast TS1, and the frame multiplexing pattern of the broadcast TS2 is calculated based on the MCCI data. Then, based on the calculated frame multiplexing pattern, a NULL packet is inserted into the TS packet of the extracted broadcast TS2, and the broadcast TS2 is reconstructed.

  On the other hand, based on the extracted MCCI data, information on the dummy byte part other than the Layer_indicator and AC_data_effective_bytes of the TS packet of the reconstructed broadcast TS2 is restored. Also, Layer_indicator and AC_data_effective_bytes of the TS packet of the reconstructed broadcast TS2 are converted to those of the broadcast TS2.

  In this way, the information of the dummy byte part of the TS packet of the broadcast TS2 is restored, and the broadcast TS2 is restored.

Hereinafter, specific embodiments will be described.
<First Embodiment>
In the first embodiment, a case where one broadcast TS is multiplexed and relayed on one broadcast TS using an STL / TTL line will be described.

  FIG. 3 is a block diagram of the first embodiment. As shown in FIG. 3, the relay apparatus 10 receives the broadcast TS1 and the broadcast TS2, and multiplexes the TS packet of the broadcast TS2 with the broadcast TS1 and sends it out. The relay device 20 receives the broadcast TS1, separates TS packets of the broadcast TS2 from the broadcast TS1, reconstructs and restores the broadcast TS2, and sends out the broadcast TS1 and the broadcast TS2.

  The relay device 10 includes the multiplexing device 1 described above, and the relay device 20 includes the reconstruction device 2 described above. For ease of understanding, a case will be described in which the relay device 10 includes the multiplexing device 1 and the relay device 20 includes the reconstruction device 2. However, the relay devices 10 and 20 are connected to the multiplexing device 1 again. Both the construction apparatus 2 and the construction apparatus 2 may be provided. In addition to the multiplexing device 1 and the relay device 20, the relay devices 10 and 20 include a receiving unit (frequency conversion) that receives a broadcast TS, a modulation unit or a demodulation unit that performs modulation or demodulation, and the like. The description is omitted because it is not different.

  First, the configuration and operation of the multiplexing device 1 included in the relay device 10 will be described.

  As illustrated in FIG. 4, the multiplexing apparatus 1 includes a NULL packet deletion unit 11, a dummy byte unit changing unit 12, and a multiplexing unit 13.

  The NULL packet deletion unit 11 deletes a NULL packet from the broadcast TS2.

  The dummy byte part changing unit 12 rewrites the dummy byte part of the TS packet of the broadcast TS2 from which the NULL packet has been deleted, with the above-described multiplexing information.

  The multiplexing unit 13 multiplexes the TS packet of the broadcast TS2 in which the dummy byte part is changed, instead of the NULL packet of the broadcast TS1.

  Subsequently, the operation of the multiplexing apparatus 1 will be described with reference to the operation flowchart of FIG.

  First, broadcast TS1 and broadcast TS2 are input to the multiplexing apparatus 1 (Step 100).

  The NULL packet deletion unit 11 deletes a NULL packet from the broadcast TS2 (Step 101).

  The dummy byte part changing unit 12 rewrites the dummy byte part of the TS packet (204 bytes) of the broadcast TS2 from which the NULL packet has been deleted. Specifically, in the TS packet (204 bytes), the actual data (188 bytes) is changed, and the information of the 8-byte dummy data portion is changed. What is changed is Layer_indicator and AC_data_effective_bytes (Step 102). The Layer_indicator is changed to the layer information of the broadcast TS2 by using an identifier (1001 to 1111) for identifying that the carrier is a TS packet that multiplexes unique data. As for AC_data_effective_bytes, 2 bytes out of 4 bytes are used for identification of each TS.

  Subsequently, the information of the dummy byte part other than Layer_indicator and AC_data_effective_bytes is changed for broadcasting TS1 (Step 103).

  The multiplexing unit 13 multiplexes the TS packet of the broadcast TS2 in which the dummy byte part is changed instead of the NULL packet of the broadcast TS1 (Step 104).

  Broadcast TS1 in which TS packets of broadcast TS2 are multiplexed is sent (Step 105).

  Next, the configuration and operation of the reconstruction device 2 included in the relay device 20 will be described.

  As shown in FIG. 6, the reconstruction device 2 includes a separation unit 21, an MCCI data extraction unit 22, a frame multiplexed pattern calculation unit 23, a dummy byte unit restoration unit 24, a NULL packet insertion unit 25, and a dummy byte unit. And a replacement unit 26.

  The separation unit 21 refers to the Layer_indicator of the dummy byte part in the TS packet of the broadcast TS1, and extracts the TS packet of the broadcast TS2 from the TS packet of the broadcast TS1.

  The MCCI data extraction unit 22 acquires an IIP (ISDB-T Information Packet) of the broadcast TS2 from the broadcast TS1, and extracts MCCI data.

  The frame multiplex pattern calculation unit 23 calculates the frame multiplex pattern of the broadcast TS2 based on the extracted MCCI data.

  The dummy byte part restoration unit 24 restores information of the dummy byte part other than Layer_indicator and AC_data_effective_bytes based on the extracted MCCI data. Further, the Layer_indicator and AC_data_effective_bytes are returned to the Layer_indicator and AC_data_effective_bytes of the broadcast TS2, and the information of the dummy byte part of the TS packet of the broadcast TS2 is restored.

  The NULL packet insertion unit 25 arranges TS packets of the broadcast TS2 in the extracted order, and inserts a NULL TS packet between the packets based on the calculated frame multiplexing pattern to reconstruct the broadcast TS2. .

  The dummy byte part replacement unit 26 replaces the dummy byte part of the reconstructed TS packet of the broadcast TS2 with the restored dummy byte part of the broadcast TS2, thereby restoring the broadcast TS2.

  Next, the operation of the reconstruction device 2 will be described using the operation flowchart of FIG.

  First, the broadcast TS1 is input to the reconstruction device 2 (Step 200).

  The separation unit 21 refers to the dummy byte part of the TS packet of the broadcast TS1, and extracts the TS packet of the broadcast TS2 from the broadcast TS1 (Step 201).

  The MCCI data extraction unit 22 acquires IIP from the broadcast TS1 and extracts MCCI data (Step 202).

  The frame multiplex pattern calculation unit 23 calculates the frame multiplex pattern of the broadcast TS2 based on the extracted MCCI data (Step 205).

  The NULL packet insertion unit 25 arranges the TS packets of the broadcast TS2 in the order of extraction, and inserts a NULL TS packet between the TS packets of the broadcast TS2 based on the calculated frame multiplexing pattern (Step 206).

  On the other hand, the dummy byte part restoration unit 24 restores information of the dummy byte part other than the Layer_indicator and AC_data_effective_bytes of the broadcast TS2 based on the extracted MCCI data (Step 203).

  Further, the dummy byte part restoration unit 24 converts Layer_indicator and AC_data_effective_bytes into those of the broadcast TS2 (Step 204).

  The dummy byte part replacement unit 26 replaces the dummy byte part information of the TS packet in the reconstructed broadcast TS2 with the restored information of the dummy byte part of the broadcast TS2 (Step 207).

  Then, the restored broadcast TS2 is sent out (Step 208).

  In addition, although it is broadcast TS1, after extracting TS packet of broadcast TS2, a NULL TS packet may be inserted instead of the TS packet of broadcast TS2. In this way, the original broadcast TS1 can be restored. Further, the broadcast TS1 may be retransmitted in a state where TS packets of the broadcast TS2 are multiplexed. On the receiving side of the broadcast TS1, since the TS packet of the broadcast TS2 is ignored and processed, there is no actual harm even if it is left as it is.

As described above, by effectively using the unused area of the broadcast TS, the frequency can be effectively used, and a new line is not required, and the cost can be reduced.
<Second Embodiment>
A second embodiment will be described.

  The second embodiment is characterized in that at least one broadcast TS is multiplexed on a plurality of broadcast TSs. In order to facilitate understanding, in the following description, an example in which broadcast TS to be multiplexed is broadcast TS2, and broadcast TS2 is multiplexed to broadcast TS1 to broadcast TSn (excluding broadcast TS2) will be described. Detailed description of the same parts as those in the first embodiment is omitted.

  FIG. 8 is a configuration diagram of the second embodiment.

  As shown in FIG. 8, in the second embodiment, broadcast TS1 to broadcast TSn are input to the relay apparatus 10, and broadcast TS2 is multiplexed and output to broadcast TS1 to broadcast TSn (except for broadcast TS2). Broadcast TS1 to broadcast TSn (excluding broadcast TS2) is input to relay device 20, and broadcast TS2 is separated and reconstructed from broadcast TS1 to broadcast TSn (excluding broadcast TS2) by relay device 20, and broadcast TS1 to broadcast TSn is output.

  Details of the relay device 10 according to the second embodiment will be described.

  FIG. 9 is a block diagram of the relay device 10 according to the second embodiment.

The relay apparatus 10 of the second embodiment is different from the relay apparatus 10 of the first embodiment in that a plurality of multiplexing difference apparatuses ₁₁ and multiplexing difference apparatuses 1 ₃ to 1 _n and a broadcast TS 2 to be multiplexed are multiplexed. the TS packet is a point and a distributor 3 for distributing to each multiplexer difference device 1 ₁ and multiplexing difference device 1 ₃ to 1 _n.

The distribution device 3 distributes the TS packets of the broadcast TS2 to be multiplexed to each of the multiplexing difference devices 1 ₁ to 1 _n , but the distribution method may be simply repeated in the order of the younger number of the broadcast TS. For example, the TS packets of the broadcast TS2 are distributed in the order of the multiplexing difference device 1 ₁ , the multiplexing difference device 1 ₃ ,..., The multiplexing difference device 1 _n , and the multiplexing difference device 1 ₁ , the multiplexing difference device 1 again. _3. Distribute repeatedly as in

Also, the Null packet of each broadcast TS to be multiplexed is measured, the average Null packet number of each broadcast TS is obtained, and the TS packet of the broadcast TS2 to be multiplexed is determined according to the ratio of the average Null packet number of each broadcast TS. it may be distributed to each multiplexer difference device 1 ₁ to 1 _n.

Next, the multiplexing difference apparatus ₁₁ and the multiplexing difference apparatuses 1 ₃ to 1 _n of the second embodiment will be described.

Multiplexing difference device 1 ₁ and multiplexing difference device 1 ₃ to 1 _n of the second embodiment is basically the same as multiplexed differential apparatus 1 of the first embodiment. However, the dummy byte part changing unit 12 assigns the TSP_counter of the dummy byte part as it is without changing the value of the TSP_counter of the TS packet of the broadcast TS2 to be multiplexed. In this way, when the broadcast TS2 is reconstructed, even when the broadcast TS2 is multiplexed with a plurality of broadcast TSs, the order of the TS packets of the broadcast TS2 is known when the broadcast TS2 is reconstructed. . The other configurations are the same.

  Subsequently, the operation of the relay apparatus 10 will be described.

  FIG. 10 is an operation flowchart of the relay device 10 according to the second embodiment.

First, (excluding broadcast TS2) broadcasting TS1~ broadcast TSn to the multiplexer difference device _{1 1} and multiplexing difference device ₁ 3 to 1 _n is inputted (Step300).

Subsequently, the TS packets of the broadcast TS2 are distributed by the distribution device 3, for example, depending on the ratio of the average number of Null packets of each broadcast TS, to each of the multiplexing difference device ₁₁ and the multiplexing difference devices 1 ₃ to 1 _n . It is input (Step 301).

Each multiplexer difference device _{1 1} and multiplexing difference device ₁ 3 to 1 _n packet deletion unit 11 from the TS packets of the input broadcast TS2, deleting the NULL packet (Step 302).

  The dummy byte part changing unit 12 rewrites the dummy byte part of the TS packet (204 bytes) of the broadcast TS2 from which the NULL packet has been deleted. Specifically, in the TS packet (204 bytes), the actual data (188 bytes) is changed, and the information of the 8-byte dummy data portion is changed. What is changed is Layer_indicator and AC_data_effective_bytes (Step 303). The Layer_indicator is changed to the hierarchy information of the broadcast TS2 by using an identifier (1001 to 1111) for identifying that the provider is a TSP that multiplexes unique data. As for AC_data_effective_bytes, 2 bytes out of 4 bytes are used for identification of each TS.

  Subsequently, regarding the information of the dummy byte part other than Layer_indicator and AC_data_effective_bytes, the value of TSP_counter is left as it is for broadcasting TS2, and other information is changed for broadcasting TS1 (Step 304).

Multiplexer 13 of the multiplexer difference device _{1 1} and multiplexing difference device ₁ 3 to 1 _n is the TS packet of the broadcast TS2 dummy byte unit is changed, multiplexes in place of NULL packets of a broadcast TS (STEP 305 ).

  Then, the broadcast TS in which the TS packet of the broadcast TS2 is multiplexed is sent (Step 306).

  Next, details of the reconstruction device 2 of the relay device 20 according to the second embodiment will be described.

  FIG. 11 is a block diagram of the reconstruction device 2 of the relay device 10 according to the second embodiment.

As shown in FIG. 11, the reconstruction device 2 according to the second embodiment includes separation units 21 ₁ and 21 _{3 to} 21 _n , an MCCI data extraction unit 22, a frame multiplexed pattern calculation unit 23, and a dummy byte unit restoration. Unit 24, a NULL packet insertion unit 25, a dummy byte part replacement unit 26, and a TSP rearrangement unit 27.

The separation units 21 ₁ and 21 _{3 to} 21 _n are the same as the separation unit 21 of the first embodiment. The frame multiplex pattern calculation unit 23, the dummy byte unit restoration unit 24, the NULL packet insertion unit 25, and the dummy byte unit replacement unit 26 are the same as those in the first embodiment.

  The MCCI data extraction unit 22 acquires an IIP (ISDB-T Information Packet) of the broadcast TS2 from each of the broadcast TS1 to broadcast TSn (excluding the broadcast TS2), and extracts MCCI data. This is because it is unclear to which broadcast TS the IIP of the broadcast TS2 is multiplexed, and it is necessary to monitor all the broadcast TSs.

The TSP rearrangement unit 27 inputs the TS packets of the broadcast TS2 extracted by the separation units 21 ₁ and 21 _{3 to} 21 _n , and sequentially sets the TS packets of the broadcast TS2 based on the value of TSP_counter of each TS packet. Rearrange and reconstruct the broadcast TS2 excluding the NULL TS packet. Note that the reordering process of the TSP reordering unit 27 operates so that the packet reordering process ends within the range because the range of the TSP_counter value is limited (the counter value is reset). To do.

  Next, the operation of the reconstruction device 2 in the second embodiment will be described. FIG. 12 is an operation flowchart of the reconstruction device 2 according to the second embodiment.

  First, each broadcast TS is input to the reconstruction device 2 (Step 400).

The separation unit separation units 21 ₁ and 21 _{3 to} 21 _n refer to the dummy byte portion of the TS packet of the broadcast TS and extract the TS packet of the broadcast TS2 from the broadcast TS (Step 401).

The TSP rearrangement unit 27 rearranges the TS packets of the broadcast TS2 in order from the TS packets of the broadcast TS2 extracted by the separation units 21 ₁ and 21 _{3 to} 21 _n based on the TSP_counter value of each TS packet. (Step 402).

  On the other hand, the MCCI data extraction unit 22 acquires the IIP of the broadcast TS2 from each broadcast TS, and extracts the MCCI data (Step 403).

  The frame multiplex pattern calculation unit 23 calculates the frame multiplex pattern of the broadcast TS2 based on the extracted MCCI data (Step 404).

  Further, the dummy byte part restoration unit 24 restores information of the dummy byte part other than the Layer_indicator and AC_data_effective_bytes of the broadcast TS2 based on the extracted MCCI data (Step 405). Further, the dummy byte part restoration unit 24 converts Layer_indicator and AC_data_effective_bytes into that of the broadcast TS2 (Step 406).

  The NULL packet insertion unit 25 reconstructs the broadcast TS2 by inserting a NULL TS packet between the TS packets of the broadcast TS2 rearranged by the TSP rearrangement unit 27 based on the calculated frame multiplexing pattern ( Step 407).

  Then, the dummy byte part replacing unit 26 replaces the information of the dummy byte part of the TS packet in the reconstructed broadcast TS2 with the information of the restored dummy byte part of the broadcast TS2 (Step 408).

  Finally, the restored broadcast TS2 is sent out (Step 409).

  In addition, although it is each broadcast TS with which broadcast TS2 was multiplexed, after extracting the TS packet of broadcast TS2, you may insert a NULL TS packet instead of the TS packet of the broadcast TS2. In this way, each original broadcast TS can be restored. Further, each broadcast TS may be retransmitted in a state where TS packets of the broadcast TS2 are multiplexed. On the receiving side of each broadcast TS, the TS packet of the broadcast TS2 is ignored and processed, so there is no actual harm even if it is left as it is.

  As described above, in addition to the effects of the first embodiment, more effective frequency utilization is possible by effectively utilizing unused areas of a plurality of broadcast TSs.

  In the above-described embodiment, the value of TSP_counter is used to rearrange the TS packets of broadcast TS2, but count_down_index of the dummy byte part may be used.

Further, when distributing TS packets to be multiplexed on the multiplexing side, identification information for identifying the broadcast TS to be distributed next may be added to the count_down_index. In this way, TS packet rearrangement processing can be performed without buffering the extracted TS packets. Since count_down_index can be reproduced from the IIP, there is no problem even if it is replaced with different information when the broadcast TS is multiplexed.
<Third Embodiment>
A third embodiment will be described.

  The third embodiment is characterized in that, in an STL / TTL line, each relay station monitors each STL / TTL line and multiplexes a broadcast TS in the STL / TTL line where a failure has occurred with another broadcast TS. To do.

  FIG. 12 is a block diagram of the relay device 10 according to the third embodiment. The difference from the second embodiment described above is that a monitoring device 4 for monitoring each line is provided.

  The monitoring device 4 monitors each STL / TTL line, and when a failure occurs in any TL / TTL line, notifies the distribution apparatus 3 of the line.

  The distribution device 3 distributes the broadcast TS on the line where the failure has occurred to the other broadcast TS as in the above-described embodiment.

Each of the multiplexing difference devices 1 ₁ to 1 _n performs the same operation as in the above-described embodiment.

  By configuring in this way, the safety of the line of each station can be increased at low cost, and it is possible to cope with interference with frequency selectivity.

  In the above-described embodiment, each unit of the relay device, the multiplexing difference device, and the reconstruction device is configured by hardware, but can also be realized by a program that causes the CPU or the like to execute the operation of each unit.

  Although the present invention has been described with reference to the preferred embodiments, the present invention is not necessarily limited to the above-described embodiments, and various modifications can be made within the scope of the technical idea.

DESCRIPTION OF SYMBOLS 1 Multiplexer 2 Reconstruction apparatus 3 Distribution apparatus 4 Monitoring apparatus 10,20 Relay apparatus 11 NULL Packet deletion part 12 Dummy byte part change part 13 Multiplexer 21 Separation part 22 MCCI data extraction part 23 Frame multiplexing pattern calculation part 24 Dummy Byte part restoration part 25 NULL packet insertion part 26 Dummy byte part replacement part 27 TSP rearrangement part

Claims (14)

A transmission system that multiplexes at least one broadcast TS (Transport Stream) with at least one other broadcast TS and transmits the multiplexed broadcast TS.
A part of information of the dummy byte part of the TS packet excluding the null packet in the predetermined broadcast TS is changed to identification information for identifying the TS packet of the predetermined broadcast TS, and other dummy byte parts The information is changed to the information of the dummy byte part of the other broadcast TS that multiplexes the broadcast TS, and the TS of the predetermined broadcast TS in which the information of the dummy byte part is changed instead of the null packet of the other broadcast TS A multiplexing means for multiplexing the packets;
Based on the identification information of the dummy byte portion, extract the TS packet of the predetermined broadcast TS from the broadcast TS multiplexed with the predetermined broadcast TS, restore the dummy byte portion of the extracted TS packet, A transmission system comprising reconstructing means for reconstructing the predetermined broadcast TS. The multiplexing means changes the layer_indicator information of the dummy byte part to identification information for identifying the predetermined broadcast TS,
The reconstructing unit extracts a TS packet of the predetermined broadcast TS from a broadcast TS in which the predetermined broadcast TS is multiplexed based on information of Layer_indicator of the dummy byte part. The transmission system described in 1. The transmission system according to claim 1, wherein the multiplexing means changes information of AC_data_effective_bytes when the TS packet of the predetermined broadcast TS transmits AC data. The reconstruction means includes
Referring to the Layer_indicator of the dummy byte part in the TS packet of the broadcast TS in which the TS packet of the predetermined broadcast TS is multiplexed, the TS packet of the predetermined broadcast TS is obtained from the broadcast TS in which the TS packet of the predetermined broadcast TS is multiplexed. Extracting means for extracting;
Frame multiplexing pattern calculation means for obtaining an IIP (ISDB-T Information Packet) of the predetermined broadcast TS, extracting MCCI data, and calculating a frame multiplexing pattern of the predetermined broadcast TS based on the MCCI data;
Based on the MCCI data of the broadcast TS in which TS packets of the predetermined broadcast TS are multiplexed, information on at least dummy bytes other than the Layer_indicator or AC_data_effective_bytes is restored. And dummy byte part restoring means for restoring the information of the dummy byte part of the TS packet in the predetermined broadcast TS,
Based on the calculated frame multiplexing pattern, a null packet is inserted between the extracted TS packets of the predetermined broadcast TS, the predetermined broadcast TS is reconstructed, and the reconstructed broadcast TS TS packet 4. The transmission system according to claim 2, further comprising: a broadcast TS restoration unit that replaces the dummy byte portion of the first byte with the restored information and restores the predetermined broadcast TS. 5. The multiplexing means has distribution means for distributing at least one TS packet of a predetermined broadcast TS to at least one other broadcast TS, and a dummy of the TS packet of the predetermined broadcast TS to be multiplexed The TSP_counter value in the byte part is set to the TSP_counter value of the TS packet of the predetermined broadcast TS,
The reconstructing means rearranges TS packets of the predetermined broadcast TS extracted from each broadcast TS based on a value of TSP_counter in the dummy byte part. The transmission system according to Crab. Monitoring each STL / TTL line through which the broadcast TS is transmitted, and monitoring means for monitoring any line failure;
6. The transmission system according to claim 5, wherein the distribution unit distributes TS packets of the broadcast TS of the line in which a failure is detected by the monitoring unit to at least one other broadcast TS. A multiplexing device that multiplexes at least one broadcast TS (Transport Stream) into at least one other broadcast TS,
A part of information of the dummy byte part of the TS packet excluding the null packet in the predetermined broadcast TS is changed to identification information for identifying the TS packet of the predetermined broadcast TS, and other dummy byte parts The information is changed to the information of the dummy byte part of the other broadcast TS that multiplexes the broadcast TS, and the TS of the predetermined broadcast TS in which the information of the dummy byte part is changed instead of the null packet of the other broadcast TS A multiplexing apparatus comprising multiplexing means for multiplexing packets. A transmission method in which at least one broadcast TS (Transport Stream) is multiplexed with at least one other broadcast TS and transmitted.
The transmission side changes the information of a part of the dummy byte part of the TS packet excluding the null packet from the predetermined broadcast TS to the identification information for identifying the TS packet of the predetermined broadcast TS, and other The information of the dummy byte part is changed to the information of the dummy byte part of another broadcast TS that multiplexes the broadcast TS, and the information of the dummy byte part is changed instead of the null packet of the other broadcast TS. Multiplex TS packets of broadcast TS,
The receiving side extracts the TS packet of the predetermined broadcast TS from the broadcast TS multiplexed with the predetermined broadcast TS based on the identification information of the dummy byte portion, and the dummy byte portion of the extracted TS packet And reconstructing the predetermined broadcast TS. The transmission side changes the information of Layer_indicator in the dummy byte part to identification information for identifying the predetermined broadcast TS,
9. The receiver according to claim 8 , wherein the receiving side extracts a TS packet of the predetermined broadcast TS from the broadcast TS in which the predetermined broadcast TS is multiplexed based on information of Layer_indicator of the dummy byte part. The transmission method described. The transmission method according to claim 8 , wherein the transmission side changes information of AC_data_effective_bytes when a TS packet of the predetermined broadcast TS transmits AC data. The receiving side
Referring to the Layer_indicator of the dummy byte part in the TS packet of the broadcast TS in which the TS packet of the predetermined broadcast TS is multiplexed, the TS packet of the predetermined broadcast TS is obtained from the broadcast TS in which the TS packet of the predetermined broadcast TS is multiplexed. Extract and
Obtaining IIP (ISDB-T Information Packet) of the predetermined broadcast TS and extracting MCCI data, calculating a frame multiplexing pattern of the predetermined broadcast TS based on the MCCI data,
Based on the MCCI data of the broadcast TS in which TS packets of the predetermined broadcast TS are multiplexed, information on at least dummy bytes other than the Layer_indicator or AC_data_effective_bytes is restored. To restore the information of the dummy byte part of the TS packet in the predetermined broadcast TS,
Based on the calculated frame multiplexing pattern, a null packet is inserted between the extracted TS packets of the predetermined broadcast TS, the predetermined broadcast TS is reconstructed, and the reconstructed broadcast TS TS packet The transmission method according to claim 9 or 10 , wherein the dummy byte part is replaced with restored information to restore the predetermined broadcast TS. The transmission side distributes at least one TS packet of a predetermined broadcast TS to at least one other broadcast TS, and sets the value of TSP_counter in the dummy byte portion of the TS packet of the predetermined broadcast TS to be multiplexed. Multiplex the TSP_counter value of the TS packet of a given broadcast TS,
12. The receiver according to claim 8 , wherein the receiving side rearranges TS packets of the predetermined broadcast TS extracted from each broadcast TS based on a value of TSP_counter of the dummy byte part. The transmission method described in 1. The sender side
Monitor each STL / TTL line on which broadcast TS is transmitted, detect any line failure,
13. The transmission method according to claim 12 , wherein a TS packet of a broadcast TS of a line in which a failure is detected is distributed to at least one other broadcast TS. A program of a multiplexing device that multiplexes at least one broadcast TS (Transport Stream) into at least one other broadcast TS,
A part of information of the dummy byte part of the TS packet excluding the null packet in the predetermined broadcast TS is changed to identification information for identifying the TS packet of the predetermined broadcast TS, and other dummy byte parts A process of changing the information to information of a dummy byte part of another broadcast TS that multiplexes the broadcast TS;
A program for causing a multiplexing device to execute a process of multiplexing a TS packet of a predetermined broadcast TS in which information of the dummy byte portion is changed instead of the null packet of the other broadcast TS.

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