JP2020170889A - Transmission signal selection device, transmission system, transmission signal selection method, and program - Google Patents

Abstract

To provide a transmission signal selection device, a transmission system, a transmission signal selection method, and a program capable of switching to a transmission signal in real time according to a reception quality situation.SOLUTION: A transmission signal selection device 1 has a PCR extraction unit 111 for extracting a PCR packet from a first TS signal transmitted on a transmission line 130, a quality information detection unit 112 for detecting first quality information related to a packet error and a packet missing situation from the first TS signal for each PCR section, a PCR extraction unit 121 for extracting a PCR packet from a second TS signal obtained by converting the first TS signal for use on an IP transmission line and transmitting it on a transmission line 140, a quality information detection unit 122 for detecting second quality information related to a packet error and a packet missing situation from the second TS signal for each PCR section, and a selection output unit 13 for selecting and outputting any one of the first TS signal and the corresponding second TS signal based on the first quality information and the corresponding second quality information.SELECTED DRAWING: Figure 1

Description

The present invention relates to a transmission signal selection device, a transmission system, a transmission signal selection method and a program, and more particularly to a transmission signal selection device, a transmission system, a transmission signal selection method and a program for selecting a transmission signal for transmitting digital broadcast contents.

Broadcast contents of digital broadcasting taken at a stadium outside the TV station are transmitted to the TV station via satellite, for example. However, in transmission via satellite, if there is a rainy area on the transmission path, a data error of the transmission line may occur due to rainfall attenuation, and broadcasting may be interrupted. In recent years, in order to realize uninterrupted broadcasting, the contents of digital broadcasting are transmitted via the IP (Internet Protocol) network, and mutual complementation of broadcasting and communication is being realized.

For example, in Patent Document 1, a content transmitting device broadcasts broadcast data including transmission data and its error-correcting first redundant data to a receiving terminal via a broadcast radio wave transmission station, and also provides error-correcting second redundant data. A content distribution system that transmits the including communication data to a receiving terminal via a communication network and a radio base station is disclosed. The broadcast data generation unit of Patent Document 1 adds a header including packet synchronization ID (IDentification) information to the transmission data and the first redundant data, and uses this as broadcast data, and the communication data generation unit uses the second redundant data. A header containing the same packet synchronization ID information as the broadcast data generation unit is added to the data, and this is used as communication data.

In the receiving terminal of Patent Document 1, when the measured value of the reception quality becomes equal to or less than the reference value, the broadcast data and the communication data are input to the data synthesis unit, and the data synthesis unit receives the packet synchronization ID included in the header of each data. Using the information, the data obtained by synthesizing the transmission data, the first redundant data, and the second redundant data at the same time is input to the error correction code decoding unit. Error correction The code decoding unit corrects the transmission data by using the first and second redundant data.

Further, Patent Document 2 discloses a broadcast communication cooperation service in which broadcast contents are transmitted by broadcasting and communication contents are transmitted by communication. The receiving device of Patent Document 2 is information for receiving broadcast content transmitted by broadcasting and reproducing the communication content transmitted by communication in synchronization with the received broadcast content, and is the acquisition of the communication content. Acquired information, which is information related to the above, is received through broadcasting, and communication contents are acquired based on the received acquired information. Further, in the receiving device of Patent Document 2, the control unit compares the PTS (Presentation Time Stamp) of the broadcast content after decoding with the PTS of the communication content, and calculates the delay time of the communication content with respect to the broadcast content. Then, the receiving device outputs the control information for matching the output timings of the broadcast content and the communication content to the synchronization buffer in the broadcast system buffer based on the delay time in the control unit. The synchronization buffer in the broadcast system buffer delays the broadcast system buffer output based on the delay time according to the control information, switches the presentation of the broadcast content from the normal presentation to the delayed presentation, and starts the presentation of the communication content.

Japanese Unexamined Patent Publication No. 2010-136000 Japanese Unexamined Patent Publication No. 2015-050768

As described above, in Patent Document 1, a header including packet synchronization ID information is added to each of the transmission data, the first redundant data, and the second redundant data. When the measured value of reception quality falls below the reference value, the transmission data, the first redundant data, and the second redundant data at the same time are combined using the packet synchronization ID information included in the header of each data to correct the error. It is input to the code decoding unit. However, Patent Document 1 does not disclose at what timing the data input to the error correction code decoding unit can be switched from the determination of the reception quality. Patent Document 1 does not disclose a configuration for switching data input to the error correction code decoding unit in real time according to the status of reception quality.

Further, in Patent Document 2, the control unit outputs control information for matching the output timing of the broadcast content and the communication content based on the delay time to delay the output of the broadcast system buffer, and presents the broadcast content normally. Switch from presentation to delayed presentation and start presenting communication content. However, Patent Document 2 does not disclose at what timing the presentation of the broadcast content and the communication content can be switched from the determination of the reception quality. Patent Document 2 does not disclose a configuration for switching the presentation of broadcast content and communication content in real time according to the status of reception quality.

An object of the present invention is to provide a transmission signal selection device, a transmission system, a transmission signal selection method and a program capable of switching transmission signals in real time according to a reception quality situation.

The transmission signal selection device on one side of the present invention is a first PCR extraction unit that extracts a first PCR (Program Lock Reference) packet from a first TS (Transport Stream) signal transmitted on a first transmission line. The first quality information detection unit that detects the first quality information related to the packet error and the missing packet situation from the first TS signal for each section between the first PCR packets, and the first TS. A second PCR extractor that extracts a second PCR packet from a second TS signal whose signal is converted for an IP (Internet Protocol) transmission line and transmitted on the second transmission line, and the second PCR packet. A second quality information detection unit that detects a second quality information related to a packet error and a packet missing situation from the second TS signal for each section in between, and the second quality information corresponding to the first quality information. It has a selection output unit that selects and outputs any one of the second TS signal corresponding to the first TS signal based on the quality information of the above.

The transmission system of one aspect of the present invention outputs the first TS signal to the first transmission line and transmits the first TS signal to the transmission signal selection device, and also transmits the first TS signal to the transmission signal selection device. The second TS signal converted for the IP transmission line is output to the second transmission line and transmitted to the transmission signal selection device, and the TS signal selected and output by the transmission signal selection device. Has a receiving device and a receiving device for receiving.

In the transmission signal selection method of one aspect of the present invention, the first PCR packet is extracted from the first TS signal transmitted on the first transmission line, and the first PCR packet is taken for each section between the first PCR packets. The first quality information related to the packet error and the missing packet situation is detected from the TS signal of the above, and the first TS signal is converted for the IP transmission line and transmitted from the second TS signal on the second transmission line. The second PCR packet is extracted, and the second quality information related to the packet error and the missing packet situation is detected from the second TS signal for each section between the second PCR packets, and the first quality is detected. One of the first TS signal and the corresponding second TS signal is selected and output based on the second quality information corresponding to the information.

The program of one aspect of the present invention comprises a process of extracting a first PCR packet from a first TS signal transmitted on a first transmission line to a computer, and a section between the first PCR packets. The process of detecting the first quality information related to the packet error and the missing packet situation from the first TS signal, and the second process in which the first TS signal is converted for the IP transmission line and transmitted on the second transmission line. The process of extracting the second PCR signal from the TS signal and the second quality information related to the packet error and the missing packet situation are detected from the second TS signal for each section between the second PCR packets. The process and the process of selecting and outputting one of the first TS signal and the corresponding second TS signal based on the second quality information corresponding to the first quality information are executed. Let me.

According to the above aspect of the present invention, it is possible to provide a transmission signal selection device, a transmission system, a transmission signal selection method and a program capable of switching transmission signals in real time according to a reception quality situation.

FIG. 1 is a block diagram showing a configuration of a transmission signal selection device according to the first embodiment. FIG. 2 is a diagram showing an example of the operation of the TS signal and the selective output unit input from each transmission line. FIG. 3 is a diagram showing a configuration of TS packets included in the TS signal. FIG. 4 is a diagram showing an example of a quality determination table included in the quality information detection unit of FIG. FIG. 5 is a flowchart showing a transmission signal selection method according to the first embodiment. FIG. 6 is a block diagram showing the configuration of the transmission signal selection device of the second embodiment. FIG. 7 is a flowchart showing a transmission signal selection method of the second embodiment. FIG. 8 is a block diagram showing the configuration of the third embodiment. FIG. 9 is a flowchart showing a transmission signal selection method according to the third embodiment. FIG. 10 is a block diagram showing a configuration of a computer that realizes the functions of each embodiment.

Next, each embodiment will be described with reference to the drawings. FIG. 1 is a block diagram showing a configuration of a transmission system according to the first embodiment. As shown in FIG. 1, the transmission system 101 is premised on a configuration in which a transmission line for transmitting a TS (Transport Stream) signal from a transmitting device 110 to a receiving device 120 is made redundant by using an IP (Internet Protocol) network. There is. The transmission device 110 outputs a TS signal (first TS signal) to the transmission line 130 and transmits the TS signal to the transmission signal selection device 1, and also converts the first TS signal for the IP transmission line into a TS signal (second TS signal). (TS signal) is output to the transmission line 140 and transmitted to the transmission signal selection device 1. Further, the receiving device 120 receives the TS signal selected and output by the transmission signal selection device 1. The transmission line 130 is a transmission line that transmits a TS signal without conversion for an IP transmission line, and is, for example, a transmission line via a communication satellite. The transmission line 140 is a transmission line that transmits a TS signal converted for an IP transmission line, and is, for example, an IP network. In these respects, the transmission system 102 of the second embodiment and the transmission system 103 of the third embodiment, which will be described later, have the same configuration as the transmission system 101 of the first embodiment.

In the transmission signal selection device 1 of the present embodiment, the TS signal transmitted from the transmission device 110 through the transmission line 130 is input to the PCR extraction unit (first PCR extraction unit) 111. Further, the TS signal converted for the IP transmission line transmitted from the transmission device 110 on the transmission line 140 is input to the PCR extraction unit (second PCR extraction unit) 121.

FIG. 2 is a diagram showing an example of the operation of the TS signal and the selective output unit input from each transmission line. As shown in FIG. 2, the TS signal input from the transmission line 130 is PCR (Program Packet Reference), which is synchronization information for synchronizing the transmitting side and the receiving side, which is defined in the MPEG-2 TS standard. Includes PCR packets containing information (first PCR packets) 201, 206, 211, 216. The TS signal also includes video packets 202, 203, 205, 207, 208, 210, 212, 213, and 215, which are packets including the video signal. The TS signal also includes packets 204, 209, and 214 including audio information, subtitle information, control information, and the like.

Similarly, the TS signal input from the transmission line 140 includes PCR packets (second PCR packets) 221 and 226, 231 and 236. The TS signal also includes video packets 222, 223, 225, 227, 228, 230, 232, 233, 235 including the video signal. In addition, the TS signal also includes packets 224, 229, and 234 including audio information, subtitle information, control information, and the like.

FIG. 3 is a diagram showing a configuration of TS packets included in the TS signal. As shown in FIG. 3, the TS packet 200 included in the TS signal is composed of the payload 2001 and the header 2002. The header 2002 includes a packet ID 2003 for identifying the type of data stored in the payload 2001. The header 2002 also includes error information 2004. The error information 2004 is, for example, TEI (Trnaport Error Indicator) or CC (Continuity Counter) defined in the MPEG-2 TS standard.

The PCR extraction unit 111 extracts PCR packets 201, 206, 211, and 216 with reference to the packet ID 2003 included in the header 2002 of the TS packet 200 transmitted and input on the transmission line 130. Similarly, the PCR extraction unit 121 extracts PCR packets 221, 226, 231 and 236 with reference to the packet ID included in the header 2002 of the TS packet 200 transmitted and input on the transmission line 140. Note that the section between two consecutive PCR packets, that is, in the example of FIG. 2, the section between PCR packet 201 and PCR packet 206, the section between PCR packet 206 and PCR packet 211, and the section between PCR packet 211 and PCR. The section between packets 216 is also referred to as a PCR section in the following description.

The quality information detection unit 112 detects quality information (first quality information) related to a packet error and a packet missing status from packets transmitted and input on the transmission line 130 for each PCR section. The quality information detection units 112 and 122 may detect, for example, the TEI included in the header 2002 of the TS packet 200 included in each PCR section as quality information. Further, the quality information detection units 112 and 122 may detect the continuity of CC included in the header 2002 of the TS packet 200 included in each PCR section as quality information.

The quality information detection units 112 and 122 may detect one or more quality information related to a packet error and a packet missing status, respectively, and output the quality information to the selection output unit 13. In this case, the selection output unit 13 determines the quality for determining the comprehensive quality information of the transmission lines 130 and 140 based on one or more quality information detected by the quality information detection units 112 and 122, respectively. A table may be provided. FIG. 4 is a diagram showing an example of a quality determination table included in the quality information detection unit of FIG. As shown in FIG. 4, the quality judgment table corresponds to the combination of the detection results of the quality information A and the quality information B related to the packet error detected from the input packet and the packet missing status, and the comprehensive quality information. It is a table that was made to. For example, the quality information A is used as the packet error information detected from the TEI included in the header 2002 of the TS packet 200 included in each PCR section, and the quality information B is used in the header 2002 of the TS packet 200 included in each PCR section. It is assumed that the information on the continuity of the included CCs is such that the higher the total quality information is, the less packet errors and packet omissions are. And as shown in FIG. 4, when the continuity of TEI and CC is NG, the numerical value of the quality information is the lowest, and the next lowest quality information is that the TEI is NG and the continuity of CC is OK. In some cases, when the TEI is OK and the continuity of CC is NG, the quality information is high, and when the continuity of TEI and CC is both OK, the numerical value of the quality information may be the highest. When the quality information A is OK, the quality information is higher than NG, and when the quality information B is OK, the quality information is higher than NG. Note that FIG. 4 is an example, and the quality information may be other information. For example, CC continuity may be detected for packets other than PCR packets in packets in the PCR section. Further, the numerical value of the quality information is not limited to the example of FIG. In this way, the selection output unit 13 sets the quality determination table shown in FIG. 4 from the quality information A and the quality information B related to the packet error detected from the input packet and the packet missing status for each first PCR section. May be referred to to determine overall quality information indicating packet errors and packet missing conditions for transmission line 130.

Similarly, from the quality information A and the quality information B related to the packet error and the packet missing situation detected from the packet transmitted and input on the transmission line 140 for each second PCR section, the selection output unit 13 is shown in FIG. The overall quality information indicating the packet error and the packet missing status regarding the transmission line 140 may be determined with reference to the quality determination table shown in 1.

Since it is assumed that the transmission line for transmitting the TS signal from the transmission device 110 to the reception device 120 has a redundant configuration using an IP network, the time received by the transmission signal selection device 1 is different, but the first There can be a one-to-one correspondence between the packet transmitted on the first transmission line 130 and the packet transmitted on the second transmission line 140. When the first quality information and the second quality information of the corresponding PCR section are input, the selection output unit 13 makes a second quality information for each PCR section based on the first quality information and the corresponding second quality information. Whichever of the first TS signal and the corresponding second TS signal has less packet error and packet omission is selected. Then, the selection output unit 13 outputs the selected TS signal to the receiving device 120.

It should be noted that each component of the transmission signal selection device of the first embodiment shown in FIG. 1 and each embodiment described later shows a block of functional units. Some or all of the components of each embodiment may be realized by any combination of the computer 50 and the program as shown in FIG. 10, for example. As an example, the computer 50 includes the following configuration.

-CPU (Central Processing Unit) 51
-ROM (Read Only Memory) 52
-RAM (Random Access Memory) 53
-Program 54 loaded into RAM 53
A storage device 55 for storing the program 54
A drive device 57 that reads and writes the recording medium 56.
-Communication interface 58 that connects to the communication network 59
-I / O interface 60 for inputting / outputting data
-Bus 61 connecting each component
Each component of each embodiment is realized by the CPU 51 acquiring and executing a program 54 that realizes these functions. For example, in the example of the transmission signal selection device 1 of FIG. 1, the PCR extraction units 111 and 121 are the first and second units in which the CPU 51 that has acquired the program 54 is transmitted on the transmission lines 130 and 140 based on the program 54. The function may be realized by extracting the first and second PCR packets from the TS signal.

Further, in the quality information detection units 112 and 122, the CPU 51 that has acquired the program 54 sets a packet error and a packet from the first and second TS signals for each section between the first and second PCR packets based on the program 54. The function may be realized by detecting the first and second quality information related to the missing situation.

Further, in the selection output unit 13, the CPU 51 that has acquired the program 54 corresponds to the first TS signal based on the second quality information corresponding to the first quality information for each PCR section based on the program 54. The function may be realized by selecting and outputting one of the two TS signals.

The program 54 that realizes the functions of each component of the embodiment may be stored in the storage device 55, the ROM 52, or the RAM 53 in advance, and may be configured to be read by the CPU 51 as needed. The program 54 may be supplied to the CPU 51 via the communication network 59, or may be stored in the recording medium 56 in advance, and the drive device 57 may read the program and supply the program to the CPU 51.

Next, the operation of this embodiment will be described. FIG. 5 is a flowchart showing a transmission signal selection method according to the first embodiment. As shown in FIG. 5, first, the PCR extraction unit 111 inputs the first TS signal transmitted on the first transmission line (step S1). Next, the PCR extraction unit 111 extracts the first PCR packet from the first TS signal (step S2). Next, the quality information detection unit 112 detects quality information related to packet error and packet missing status from the first TS signal for each first PCR section. The quality information detection unit 112 outputs the quality information related to the packet error and the packet missing status detected from the first TS signal to the selection output unit 13 (step S3).

Further, the TS signal is converted for the IP transmission line, and the second TS signal transmitted on the second transmission line is input to the PCR extraction unit 121 (step S4). The PCR extraction unit 121 extracts the second PCR packet from the second TS signal (step S5). Next, the quality information detection unit 122 detects the quality information related to the packet error and the packet missing status from the second TS signal for each second PCR section. The quality information detection unit 122 outputs the quality information related to the packet error and the packet missing status detected from the second TS signal to the selection output unit 13 (step S6).

Then, when the first quality information and the corresponding second quality information of the corresponding PCR section are input, the selection output unit 13 inputs the first quality information and the corresponding second quality information for each PCR section. Based on this, one of the first TS signal and the corresponding second TS signal, whichever has less packet error and packet omission, is selected and output to the receiving device 120 (step S7).

The operation of the selection output unit 13 in step S7 will be described in detail with reference to FIG. In the example shown in FIG. 2, the section between PCR packet 206 and PCR packet 211 corresponds to the section between PCR packet 221 and PCR packet 226. Therefore, the selection output unit 13 determines the quality of the first quality information output from the quality information detection unit 112 for the section between the PCR packet 206 and the PCR packet 211 and the quality of the section between the PCR packet 221 and the PCR packet 226. The second quality information output from the information detection unit 122 is compared. For example, as shown in FIG. 2, the first quality information shows that the section between the PCR packet 206 and the PCR packet 211 has few omissions, and the section between the PCR packet 221 and the PCR packet 226 has many packet omissions. It is assumed that this is shown in the second quality information. In this case, the selection output unit 13 selects the first TS signal with few packet omissions, that is, the packet input between the PCR packet 206 and the PCR packet 211, and outputs the packet to the receiving device 120.

Next, the section between PCR packet 211 and PCR packet 216 corresponds to the section between PCR packet 226 and PCR packet 231. Therefore, the selection output unit 13 determines the quality of the first quality information output from the quality information detection unit 112 for the section between the PCR packet 211 and the PCR packet 216 and the quality of the section between the PCR packet 231 and the PCR packet 236. The second quality information output from the information detection unit 122 is compared. For example, as shown in FIG. 2, the second quality information shows that the section between PCR packet 226 and PCR packet 231 has few omissions, and the section between PCR packet 211 and PCR packet 216 has no packet omission. It is assumed that many are shown in the first quality information. In this case, the selection output unit 13 selects a second TS signal with few packet omissions, that is, a packet input between the PCR packet 226 and the PCR packet 231 and outputs the packet to the receiving device 120.

As described above, according to the first embodiment, the PCR packet is extracted from the TS signal transmitted on each transmission line, and the packet error and the packet missing status of each transmission line are checked for each section between the PCR packets. The TS signal is selected and output based on the indicated quality information. As a comparative example, for example, when considering a configuration in which PTS is extracted and the route is switched as described in Patent Document 2, the interval at which PTS is transmitted in the TS signal is wider than the interval at which PCR packets are transmitted. Also, the intervals are different. Therefore, in a configuration in which PTS is extracted and the route is switched, it is difficult to switch in real time. On the other hand, the timing at which the PCR packet is transmitted is a substantially constant cycle, and the PCR packet is transmitted at intervals of 100 ms at the maximum. Therefore, according to the first embodiment, it is possible to switch the transmission signal in real time according to the reception quality situation.

Next, the second embodiment will be described. FIG. 6 is a block diagram showing the configuration of the transmission signal selection device of the second embodiment. As shown in FIG. 6, in the transmission signal selection device 2 of the present embodiment, the quality information detection unit 114 is different in that it includes a CC (Continuity Counter: continuity index) confirmation unit 1141 and a TEI confirmation unit 1142. .. Further, in the transmission signal selection device 2 of the present embodiment, the quality information detection unit 124 is different in that it includes a CC confirmation unit 1241 and a TEI confirmation unit 1242.

Note that CC is information specified to be included in the header of a TS packet in the MPEG2-TS standard, and is information that is incremented by 1 for each packet ID. Therefore, by extracting packets with the same packet ID and checking the continuity of CC, it is possible to confirm the presence or absence of missing packets.

The CC confirmation unit 1141 refers to the CC included in the header 2002 of the TS packet 200 for each first PCR section, detects, for example, the continuity of CC of the video packet (no omission), and CC confirmation result (first). (CC confirmation result of 1) is output. Similarly, the CC confirmation unit 1241 detects the continuity of CC of, for example, a video packet by referring to the CC included in the header 2002 of the TS packet 200 for each second PCR section, and CC confirmation result (second CC confirmation). The result) is output to the selection output unit 14. Note that the CC confirmation units 1141 and 1241 may detect the continuity of CC of packets other than video packets in the packets of the PCR section.

Further, the TEI confirmation unit 1142 detects the TEI included in the header 2002 of the input TS packet for each first PCR section, and uses the TEI confirmation result (first TEI confirmation result) as quality information in the selection output unit 14. Output. Similarly, the TEI confirmation unit 1242 detects the TEI included in the header 2002 of the input TS packet 200 for each second PCR section, and selects and outputs the TEI confirmation result (second TEI confirmation result) as quality information. Output to 14.

The quality information determination unit 141 of the selection output unit 14 determines comprehensive quality information regarding the transmission line 130 from the first CC confirmation result and the first TEI confirmation result for each first PCR section. As shown in FIG. 4, the selection output unit 14 of the present embodiment has a first combination of quality information A such as the first CC confirmation result and quality information B such as the first TEI confirmation result. A quality determination table 142 corresponding to quality information may be provided. Even if the quality information determination unit 141 determines the comprehensive quality information regarding the transmission line 130 with reference to the quality determination table 142 as shown in FIG. 4 for each first PCR section and outputs it to the selection control unit 144. Good.

Similarly, the quality information determination unit 143 determines comprehensive quality information regarding the transmission line 140 from the second CC confirmation result and the second TEI confirmation result for each second PCR section. The quality information determination unit 143 determines the second quality information related to the packet error and the packet missing situation with reference to the quality determination table 142 as shown in FIG. 4 for each second PCR section, and the selection control unit 144. It may be output to.

Then, as in the first embodiment, the selection control unit 144 corresponds to the first quality information for each PCR section when the first quality information and the second quality information of the corresponding PCR section are input. Based on the second quality information, one of the first TS signal and the corresponding second TS signal, whichever has less packet error and packet omission, is selected and output to the receiving device 120.

Next, the operation of this embodiment will be described. FIG. 7 is a flowchart showing a transmission signal selection method of the second embodiment. As shown in FIG. 7, first, in the PCR extraction unit 111, the first TS signal transmitted through the first transmission line 130 is input (step S1), as in the first embodiment. Next, the PCR extraction unit 111 extracts the first PCR packet from the first TS signal (step S2).

Next, in the present embodiment, the TEI confirmation unit 1142 detects the TEI from the first TS signal as quality information related to the packet error situation for each first PCR section, and the TEI confirmation result (first TEI). The confirmation result) is output to the selection output unit 23 as quality information (first quality information) (step S11). Further, in the present embodiment, the CC confirmation unit 1141 detects, for example, the continuity of CC of the video packet as quality information related to the packet missing status from the first TS signal for each first PCR section, and the CC confirmation result. (First CC confirmation result) is output to the selection output unit 14 (step S12). Then, the quality information determination unit 141 of the selection output unit 14 determines the comprehensive quality information regarding the transmission line 130 based on the first TEI confirmation result and the first CC confirmation result, and outputs the comprehensive quality information to the selection control unit 144 ( Step S13).

Further, in the PCR extraction unit 121, the TS signal is converted for the IP transmission line and the second TS signal transmitted on the second transmission line 140 is input (step S4), as in the first embodiment. Next, the PCR extraction unit 121 extracts the second PCR packet from the second TS signal (step S5).

Next, in the present embodiment, the TEI confirmation unit 1242 detects the TEI from the second TS signal as related information related to the packet error situation for each second PCR section, and the TEI confirmation result (second TEI). The confirmation result) is output to the selection output unit 14 (step S14). Further, in the present embodiment, the CC confirmation unit 1241 detects, for example, the CC continuity of the video packet as quality information related to the packet missing status from the second TS signal for each second PCR section, and the CC confirmation result. (Second CC confirmation result) is output to the selection output unit 14 (step S15). Then, the quality information determination unit 143 of the selection output unit 14 determines the comprehensive quality information regarding the transmission line 140 based on the second TEI confirmation result and the second CC confirmation result, and outputs the comprehensive quality information to the selection control unit 144 ( Step S16).

When the first quality information and the corresponding second quality information of the corresponding PCR section are input, the selection control unit 144 performs the first quality information and the correspondence for each PCR section as in the first embodiment. Based on the second quality information to be performed, one of the first TS signal and the corresponding second TS signal, whichever has less packet error and packet omission, is selected and output to the receiving device 120 (step S7).

Also in the second embodiment described above, as in the first embodiment, PCR packets are extracted from the TS signals transmitted in each transmission line, and packet errors in each transmission line are generated for each section between the PCR packets. The TS signal is selected and output based on the quality information indicating the packet missing status. With this configuration, it is possible to switch to a transmission signal in real time according to the reception quality situation.

Next, a third embodiment will be described. FIG. 8 is a block diagram showing the configuration of the third embodiment. As shown in FIG. 8, in the transmission signal selection device 3 of the present embodiment, the quality information detection unit 115 includes the PCR interval detection unit 1153, and similarly, the quality information detection unit 125 includes the PCR interval detection unit 1253. It differs from the second embodiment in that it is provided. The PCR interval detection unit 1153 counts the number of packets included in the first TS signal (first PCR interval) for each PCR section based on the timing at which the PCR packets are extracted by the PCR extraction unit 111. That is, the PCR interval detection unit 1153 detects the number of packets included in the first PCR section of the first TS signal (first PCR interval) as quality information related to the packet missing situation. Similarly, the PCR interval detection unit 1253 counts the number of packets included in the second TS signal (second PCR interval) for each PCR section based on the timing when the PCR packets are extracted by the PCR extraction unit 121. That is, the PCR interval detection unit 1253 detects the number of packets included in the second PCR section of the second TS signal (second PCR interval) as quality information related to the packet missing situation.

Similar to the second embodiment, the CC confirmation unit 1151 refers to the CC included in the header 2002 of the TS packet 200 for each first PCR section, detects, for example, the continuity of the CC of the video packet, and CC confirmation result. (The first CC confirmation result) is output to the selection output unit 15 as quality information. Similarly, as in the second embodiment, the CC confirmation unit 1251 refers to the CC included in the header 2002 of the TS packet 200 for each first PCR section, detects, for example, the continuity of the CC of the video packet, and CCs. The confirmation result (second CC confirmation result) is output to the selection output unit 15 as quality information.

Further, the TEI confirmation unit 1152 refers to the TEI included in the header 2002 of the input TS packet 200 for each first PCR section as in the second embodiment, and refers to the TEI confirmation result (first TEI confirmation result). Is output. Similarly, the TEI confirmation unit 1252 refers to the TEI included in the header 2002 of the input TS packet 200 for each second PCR section as in the second embodiment, and refers to the TEI confirmation result (first TEI confirmation result). ) Is output.

The quality information determination unit 151 of the selection output unit 15 determines the overall quality of the transmission line 130 from each of the first PCR sections, for example, the continuity of CC of the video packet, the TEI, and the number of packets in the first PCR interval. Determine the information. Similar to the second embodiment, the selection output unit 15 determines the quality by associating, for example, the continuity of CC of the video packet, the combination of TEI and the number of packets at the first PCR interval, and the comprehensive quality information. A table 152 may be provided. The quality information determination unit 151 determines comprehensive quality information regarding the transmission line 130 for each first PCR section, for example, with reference to such a quality determination table, and outputs the comprehensive quality information to the selection control unit 154.

Similarly, the quality information determination unit 153 determines comprehensive quality information regarding the transmission line 140 from, for example, the continuity of CC of video packets, TEI, and the number of packets in the second PCR interval. The quality information determination unit 153 determines comprehensive quality information regarding the transmission line 140 for each second PCR section, for example, with reference to such a quality determination table, and outputs the comprehensive quality information to the selection control unit 154.

Then, as in the first and second embodiments, the selection control unit 154 receives the quality information of the corresponding PCR section, and receives the first TS signal for each PCR section based on the respective quality information. Of the corresponding second TS signals, the one with less packet error and packet omission is selected and output to the receiving device 120.

Next, the operation of this embodiment will be described. FIG. 9 is a flowchart showing a transmission signal selection method according to the third embodiment. As shown in FIG. 7, first, in the PCR extraction unit 111, the first TS signal transmitted on the transmission line 130 is input (step S1), as in the first and second embodiments. Next, the PCR extraction unit 111 extracts the first PCR packet from the first TS signal (step S2).

Next, the TEI confirmation unit 1152 detects the TEI from the first TS signal for each first PCR section as in the second embodiment, and the TEI confirmation result (first) as quality information related to the packet error situation. The TEI confirmation result of 1) is output to the selection output unit 15 (step S11). Further, the CC confirmation unit 1151 detects, for example, the continuity of CC of the video packet (whether there is any omission) from the first TS signal for each first PCR section as in the second embodiment, and the packet is missing. The CC confirmation result (first CC confirmation result) is output to the selection output unit 15 as quality information related to the situation (step S12).

Further, in the present embodiment, the PCR interval detection unit 1153 detects the number of packets included in the first PCR section of the first TS signal (first PCR interval) as quality information related to the packet missing situation (first PCR interval). Step S21). Then, the quality information determination unit 151 of the selection output unit 15 determines comprehensive quality information (first) regarding the transmission line 130 based on the first TEI confirmation result, the first CC confirmation result, and the first PCR interval. (Quality information) is determined and output to the selection control unit 154 (step S22).

Further, the PCR extraction unit 121 also inputs the second TS signal transmitted through the transmission line 140, as in the first and second embodiments (step S4). Next, the PCR extraction unit 121 extracts the second PCR packet from the second TS signal (step S5).

Next, the TEI confirmation unit 1252 detects the TEI from the second TS signal for each second PCR section as in the second embodiment, and the TEI confirmation result (first) as quality information related to the packet error situation. The TEI confirmation result of 2) is output to the selection output unit 15 (step S14). Further, the CC confirmation unit 1251 detects, for example, the continuity of CC of the video packet (whether there is any omission) from the second TS signal for each second PCR section as in the second embodiment, and the packet is missing. The CC confirmation result (second CC confirmation result) is output to the selection output unit 15 as quality information related to the situation (step S15).

Further, in the present embodiment, the PCR interval detection unit 1253 detects the number of packets (second PCR interval) included in the second PCR section of the second TS signal as quality information related to the packet missing situation (2nd PCR interval). Step S23). Then, the quality information determination unit 153 of the selection output unit 15 determines comprehensive quality information (second) regarding the transmission line 140 based on the second TEI confirmation result, the second CC confirmation result, and the second PCR interval. (Quality information) is determined and output to the selection control unit 154 (step S24).

When the first quality information and the corresponding second quality information are input, the selection control unit 154 sets the first quality information and the corresponding second quality information for each PCR section as in the first and second embodiments. Based on the quality information of 2, one of the first TS signal and the corresponding second TS signal, whichever has less packet error and packet omission, is selected and output to the receiving device 120 (step S7).

Also in the third embodiment described above, as in the first and second embodiments, PCR packets are extracted from the TS signals transmitted in each transmission line, and each transmission line is divided into sections between the PCR packets. The TS signal is selected and output based on the quality information indicating the packet error and the packet missing status. With this configuration, it is possible to switch to a transmission signal in real time according to the reception quality situation.

The PCR interval detection units 1153 and 1253 may count the number of packets in the first and second PCR intervals and detect the continuity of the PCR packets. That is, the PCR interval detection unit 1153 checks the PCR value contained in the PCR packet when the PCR packet is extracted by the PCR extraction units 111 and 121, and determines whether the PCR value is increased by a constant amount having an allowable range. The continuity of PCR packets may be detected.

In this case, the quality information determination unit 151 determines the continuity of the CC of the video packet, the TEI, the number of packets at the first PCR interval, and the continuity of the first PCR packet for each first PCR section. Determine overall quality information about transmission line 130. Similarly, the quality information determination unit 152 determines the continuity of the CC of the video packet, the TEI, the number of packets in the second PCR interval, and the continuity of the second PCR packet for each second PCR section. Determine overall quality information about transmission line 140.

Further, in the quality determination table 152, for example, the CC continuity of the video packet, the TEI, the number of packets at the PCR interval, the combination of the continuity of the first PCR packet, and the comprehensive quality information are associated with each other. A quality determination table may be provided. In this case, in step S21, the PCR interval detection unit 1153 uses the number of packets (first PCR interval) included in the first PCR section of the first TS signal and the first as quality information related to the packet missing situation. PCR packet continuity (first PCR continuity) is detected. Then, in step S22, the quality information determination unit 151 of the selection output unit 15 determines the transmission line 130 based on the first TEI confirmation result, the first CC confirmation result, the first PCR interval, and the first PCR continuity. Comprehensive quality information (first quality information) is determined and output to the selection control unit 154.

Similarly, in step S23, the PCR interval detection unit 1253 uses the number of packets (second PCR interval) included in the second PCR section of the second TS signal and the second PCR interval as quality information related to the packet missing situation. The continuity of PCR packets (second PCR continuity) is detected. Then, in step S24, the quality information determination unit 153 of the selection output unit 15 determines the transmission path based on the second TEI confirmation result, the second CC confirmation result, the second PCR interval, and the second PCR continuity. Comprehensive quality information (second quality information) regarding 140 is determined and output to the selection control unit 154.

Even with such a configuration, as in the first, second, and third embodiments, PCR packets are extracted from the TS signals transmitted on each transmission line, and packets on each transmission line are extracted for each section between PCR packets. The TS signal is selected and output based on the quality information indicating the error and packet missing status. With this configuration, it is possible to switch to a transmission signal in real time according to the reception quality situation.

For the sake of simplicity, each of the above embodiments has been described with reference to an example in which a transmission line for transmitting a TS signal from a transmitting device to a receiving device is made redundant by two transmission lines, but the present invention is not limited to this. The present invention may be applied to a configuration in which a transmission line for transmitting a TS signal from a transmitting device to a receiving device is made redundant by three or more transmission lines.

Although the present invention has been described above with reference to the embodiments, the present invention is not limited to the above embodiments. Various changes that can be understood by those skilled in the art can be made to the structure and details of the present invention within the scope of the present invention.

1, 2, 3 Transmission signal selection device 111, 121 PCR extraction unit 112, 114, 115, 122, 124, 125 Quality information detection unit 1151, 1251 CC confirmation unit 1152, 1252 TEI confirmation unit 1153, 1253 PCR interval detection unit 13 , 14, 15 Selective output unit 141, 143, 151, 153 Quality information determination unit 142, 152 Quality judgment table 144, 154 Selective control unit 101, 102, 103 Transmission system 110 Transmission device 120 Receiver device 130, 140 Transmission line 200 TS Packets 201, 206, 211, 216 PCR packets 221, 226, 231, 236 PCR packets 202, 203, 205, 207, 208 Video packets 204, 209, 214 packets 222, 223, 225, 227, 228 Video packets 224, 229 234 Packet 2001 Packet 2002 Header 2003 Packet ID
2004 Error Information 50 Computer 51 CPU
52 ROM
53 RAM
54 Program 55 Storage device 56 Recording medium 57 Drive device 58 Communication interface 59 Communication network 60 Input / output interface 61 Bus

Claims (9)

A first PCR extraction unit that extracts a first PCR packet from a first TS signal transmitted on a first transmission line, and a first PCR extraction unit.
A first quality information detection unit that detects first quality information related to a packet error and a packet missing situation from the first TS signal for each section between the first PCR packets.
A second PCR extraction unit that extracts the second PCR packet from the second TS signal that is converted from the first TS signal for the IP transmission line and transmitted on the second transmission line,
A second quality information detection unit that detects second quality information related to packet errors and missing packets from the second TS signal for each section between the second PCR packets.
A selection output unit that selects and outputs any one of the second TS signals corresponding to the first TS signal based on the second quality information corresponding to the first quality information.
Transmission signal selection device having. The first quality information detection unit detects one or more of the first quality information from the first TS signal for each section between the first PCR packets.
The second quality information detection unit detects one or more of the second quality information from the second TS signal for each section between the second PCR packets.
The selection output unit selects one of the first TS signal and the second TS signal corresponding to the first TS signal based on one or more of the first quality information and one or more of the second quality information. And output
The transmission signal selection device according to claim 1. The first quality information detection unit has a first TEI confirmation unit that detects TEI included in the header of the first TS packet for each section between the first PCR packets.
The second quality information detection unit has a second TEI confirmation unit that detects the TEI included in the header of the second TS packet for each section between the second PCR packets.
The transmission signal selection device according to claim 1 or 2. The first quality information detection unit includes a third CC confirmation unit that detects the continuity of CCs other than the PCR packets in the section between the first PCR packets for each section between the first PCR packets. Have and
The second quality information detection unit includes a fourth CC confirmation unit that detects the continuity of CCs other than the PCR packets in the section between the second PCR packets for each section between the second PCR packets. Have,
The transmission signal selection device according to any one of claims 1 to 3. The first quality information detection unit has a first PCR interval detection unit that counts the number of packets included in the first TS signal for each section between the first PCR packets.
The first quality information detection unit has a second PCR interval detection unit that counts the number of packets included in the first TS signal for each section between the first PCR packets.
The transmission signal selection device according to any one of claims 1 to 4. The first PCR interval detection unit detects the continuity of the first PCR packet by increasing the PCR value of the first PCR packet.
The second PCR interval detection unit detects the continuity of the second PCR packet by increasing the PCR value of the second PCR packet.
The transmission signal selection device according to claim 5. The transmission signal selection device according to any one of claims 1 to 6.
The first TS signal is output to the first transmission line and transmitted to a transmission signal selection device, and the second TS signal obtained by converting the first TS signal for an IP transmission line is used as the second TS signal. A transmission device that outputs to the transmission line of the above and transmits it to the transmission signal selection device, and
A receiving device that receives the TS signal selected and output by the transmission signal selection device, and
Transmission system with. The first PCR packet is extracted from the first TS signal transmitted on the first transmission line, and the first PCR packet is extracted.
The first quality information related to the packet error and the packet missing situation is detected from the first TS signal for each section between the first PCR packets.
The first TS signal is converted for the IP transmission line, and the second PCR packet is extracted from the second TS signal transmitted on the second transmission line.
For each section between the second PCR packets, the second quality information related to the packet error and the packet missing situation detected from the second TS signal is detected.
One of the second TS signals corresponding to the first TS signal is selected and output based on the second quality information corresponding to the first quality information.
Transmission signal selection method. On the computer
The process of extracting the first PCR packet from the first TS signal transmitted on the first transmission line, and
A process of detecting a first quality information related to a packet error and a packet missing situation from the first TS signal for each section between the first PCR packets.
A process in which the first TS signal is converted for an IP transmission line and a second PCR packet is extracted from the second TS signal transmitted on the second transmission line.
A process of detecting a second quality information related to a packet error and a packet missing situation from the second TS signal for each section between the second PCR packets.
A process of selecting and outputting one of the second TS signals corresponding to the first TS signal based on the second quality information corresponding to the first quality information.
A program that runs.

Images