JP2021073809A - Multiplexing device, switching device, transmission system, and transmission method - Google Patents

Abstract

To materialize seamless switching which does not require analysis of video data and audio data, by enabling a switching point of a TLV packet between a main system and a redundant system to be identified.SOLUTION: According to an embodiment, a multiplexing device detects a switching point MMTP packet which corresponds to a switching point between a main system and a redundant system from an MMTP packet converted into a TLV packet, generates the TLV packet from the MMTP packet, and generates the TLV packet which corresponds to the switching point by assigning one of undefined packet types in the TLV packet as a switching point MMTP packet.SELECTED DRAWING: Figure 1

Description

An embodiment of the present invention relates to a multiplexing device, a switching device, a transmission system, and a transmission method for a hybrid content distribution service in which broadcasting and communication are linked.

Conventionally, the MMT (MPEG Media Transport) method has been adopted as a data multiplexing method for 4K and 8K broadcasting as a new multiplexing method for realizing a hybrid content distribution service in which broadcasting and communication are linked. In a transmission system that employs the MMT method, a redundant configuration consisting of two or more systems may be formed so that the function can be maintained even if a failure occurs. Then, if a failure occurs in the main system or maintenance is required, the switching device switches from the main system to the redundant system. Therefore, it is desired that such a switching device seamlessly switches between the main system and the redundant system as much as possible. Non-Patent Document 1 describes "MMT operation guideline at the time of switching redundant system" as a specific operation rule.

The "MMT operation guideline at the time of redundant system switching" describes the transmitting side guideline and the receiving side guideline, and the transmitting side guideline specifically describes the following.

(Guideline T1.1)
The redundant system transmission system should match the GOP (Group of Pictures) phase with the main line system transmission system as much as possible. In addition, the system should be switched in consideration of matching with the pointer slot information transmitted two frames ahead of the main line signal.
MPU (Media Processing Unit) Switching in consideration of the consistency of the relationship between the time stamp and MPU.

(Guideline T1.2)
When the processing content changes, the version number should be changed further on the sending side to prevent the version number from changing due to redundant switching.

(Guideline T1.3)
System switching should be performed with the audio muted as much as possible.

When seamlessly switching between the main system and the redundant system according to such a transmission side guideline, the coding device performs a process of aligning the GOP phases of the main system and the redundant system, and a switching point is created in the video data and the audio data. Will be done.

Accordingly, the switching point is identified by the switching device, and the system is switched from the main system to the redundant system at the switching point.

ARIB TR-B39 Volume 7 Chapter 5 5.6 MMT Operation Guidelines for Redundant System Switching

However, such a conventional method has the following problems.

That is, since the transmission format of the TLV packet cannot add information indicating the switching point, the switching device needs to analyze the video data, audio data, etc. included in the TLV packet, which imposes a load on the analysis process. There is a problem.

An object to be solved by the present invention is to provide a multiplexing device that can identify a switching point of a TLV packet between a main system and a redundant system. In addition, by providing a switching device, a transmission system, and a transmission method that realize seamless switching of TLV packets between a main system and a redundant system without analyzing video data, audio data, and the like. is there.

The multiplexing device of the embodiment is applied to a transmission system including a main system and a redundant system for transmitting TLV packets, and is a multiplexing device provided in each of the main system and the redundant system, and is a detection device. A unit, a packetization unit, and a packet generation unit are provided. The detection unit detects the switching point MMTP packet corresponding to the switching point between the main system and the redundant system from the MMTP (MPEG Media Transport Protocol) packet converted into the TLV packet. The packetizing unit generates the TLV packet from the MMTP packet. The packet generation unit generates a TLV packet corresponding to the switching point by allocating any of the packet types undefined in the TLV packet as the switching point MMTP packet.

It is a block diagram which shows the whole structure example of the transmission system to which the transmission method of embodiment of this invention is applied. It is a block diagram which shows the structural example of a coding apparatus. It is a figure which shows the structure of the MMTP packet defined in ARIB STD-B60. It is a figure which shows the structure (ARIB STD-B60) of the MMTP payload. It is a block diagram which shows the structural example of the TLV multiplexing apparatus. It is a figure which shows the structure of the TLV packet defined by ARIB STD-B32. It is a figure which shows the assignment of the "packet type" in the TLV packet defined by ARIB STD-B32. It is a block diagram which shows the configuration example of a redundant switching device. It is a flowchart (1/3) which shows the operation example of the transmission system to which the transmission method of embodiment of this invention is applied. It is a flowchart (2/3) which shows the operation example of the transmission system to which the transmission method of embodiment of this invention is applied. It is a flowchart (3/3) which shows the operation example of the transmission system to which the transmission method of embodiment of this invention is applied.

Hereinafter, a transmission system to which the transmission method according to the embodiment of the present invention is applied will be described with reference to the drawings.

(Overall configuration of transmission system)
FIG. 1 is a block diagram showing an overall configuration example of a TLV packet transmission system 10 that transmits a TLV packet as an example of a transmission system to which the transmission method of the embodiment of the present invention is applied.

The TLV packet transmission system 10 of the embodiment of the present invention includes two systems, a main system and a redundant system, for transmitting a TLV packet which is an example of a broadcast signal. The TLV packet transmission system 10 includes an FPGA (field-programmable gate array) or CPU (Central Processing Unit) or a combination thereof and a program memory (for example, SSD (Solid State Drive), HDD (Hard Disk Drive), etc.) constituting the computer. It has a non-volatile memory that can be written and read at any time), and as a control function required to implement this embodiment, the coding device 20 (# 1) and the MMT multiplexing device 30 (# 1) are the main systems. ), Scrambler 50 (# 1), IP multiplexing device 60 (# 1), TLV multiplexing device 70 (# 1), and as a redundant system, encoding device 20 (# 2), MMT multiplexing device 30. (# 2), scrambler 50 (# 2), IP multiplexing device 60 (# 2), TLV multiplexing device 70 (# 2) are provided, and the main system and redundant system are installed after the main system and redundant system. The redundant switching device 90 common to the above is provided. All of these control functions are realized by causing the FPGA or CPU to execute the program stored in the program memory.

Further, the TLV is such that an external input is made to the coding devices 20 (# 1), 20 (# 2), the TLV multiplexing device 70 (# 1), 70 (# 2), and the redundant switching device 90. An external input device 100 is connected to the packet transmission system 10.

(Encoding device)
FIG. 2 is a block diagram showing a configuration example of the coding device 20.

The encoding devices 20 (# 1) and 20 (# 2) convert, for example, a video signal, an audio signal, and a subtitle signal input from a broadcast master system (not shown) into a broadcast signal in the form of an MMTP (MPEG Media Transport Protocol) packet. It is a device for conversion, and includes a switching control receiving unit 21, a GOP phase adjusting unit 22, a signal coding unit 23, a switching information setting unit 24, and an MMTP packetizing unit 25. Since the coding devices 20 (# 1) and 20 (# 2) both have the same configuration, the above description of each component will be described below without distinguishing between the main system and the redundant system.

The signal coding unit 23 receives, for example, a video signal, an audio signal, and a subtitle signal input from a broadcast master system (not shown), encodes (compresses) each of the received signals, and encodes (compresses) each of the received signals. The video signal, audio signal, and subtitle signal are output to the switching information setting unit 24 and the MMTP packetization unit 25, respectively.

The switching control receiving unit 21 receives a request for switching between the main system and the redundant system from the external input device 100. Then, when the switching control receiving unit 21 receives the switching request, the GOP phase adjusting unit 22, the switching information setting unit 24, and the MMTP packetizing unit 25 are combined with the main system and the redundant system as described below. Executes the process for switching.

After receiving the request from the switching control receiving unit 21, the GOP phase adjusting unit 22 outputs an adjusting signal for aligning the GOP (Group of Pictures) phases of the video signal, the audio signal, and the subtitle signal to the switching information setting unit 24. To do.

The switching information setting unit 24 sets a predetermined value (for example, 0) to the MPU (Media Processing Unit) sequence number included in the MMTP packet corresponding to the switching point between the main system and the redundant system determined based on the adjustment signal. Generate instructional input to set. Then, this instruction input is output to the MMTP packetization unit 25.

Alternatively, the switching information setting unit 24 sets the least significant bit of the time stamp field included in the MMTP packet corresponding to the switching point between the main system and the redundant system determined based on the adjustment signal to a predetermined value (for example, 0). ) Is generated. Then, this instruction input is output to the MMTP packetization unit 25.

FIG. 3 is a diagram showing a configuration of an MMTP packet defined by ARIB STD-B60, which is a standard of ARIB (Association of Radio Industries and Businesses). Further, FIG. 4 is a diagram showing a configuration (ARIB STD-B60) of the MMTP payload shown by a box at the end of the data structure of FIG. The MPU_sequence_number indicated by the box in FIG. 4 is the MPU sequence number.

The MMTP packetizing unit 25 packetizes the video signal, the audio signal, and the subtitle signal encoded (compressed) by the signal coding unit 23, and generates each MMTP packet.

In this way, the MMTP packetizing unit 25 outputs the MMTP packets of the video signal, the audio signal, and the subtitle signal to the MMT multiplexing device 30 in a state where the switching points can be identified.

It should be noted that the broadcast master system does not always input three types of signals, a video signal, an audio signal, and a subtitle signal, to the encoding device 20, and only one or two of these signals are input. In some cases. For example, when only a video signal is input from the broadcast master system to the coding device 20, the coding device 20 outputs only the MMTP packet of the video signal to the MMT multiplexing device 30. When a video signal and an audio signal are input from the broadcast master system to the encoding device 20, the encoding device 20 outputs the MMTP packet of the video signal and the MMTP packet of the audio signal to the MMT multiplexing device 30. And so on.

(MMT multiplexing device)
The MMT multiplexing devices 30 (# 1) and 30 (# 2) both have the same configuration, and the MMTP packet (MMTP packet) output by the corresponding coding devices 20 (# 1) and 20 (# 2) is used. For example, MMTP packets for video signals, MMTP packets for audio signals, and MMTP packets for subtitles) and MMTP packet format data output from an EPG (electronic program guide) transmitter (not shown) are multiplexed and multiplexed. The MMTP packet is output to the scrambler 50 of the same system. In addition, the MMT multiplexing devices 30 (# 1) and 30 (# 2) also internally generate (reconstruct) the MMT-SI such as a PA message, if necessary.

(Scrambler)
The scrambler 50 (# 1) and 50 (# 2) both have the same configuration, and for the MMTP packet output from the corresponding MMT multiplexing devices 30 (# 1) and 30 (# 2), respectively. Then, encryption is performed for copyright protection, and the encrypted MMTP packet is output to the IP multiplexing device 60 of the same system. Since encryption is not essential, the scrambler 50 may not be provided.

The IP multiplexing devices 60 (# 1) and 60 (# 2) both have the same configuration, and MMTP packets output from the corresponding scramblers 50 (# 1) and 50 (# 2) are output. , Multiplex with IP packet format data from other devices (not shown). Then, the MMTP packet and the IP packet obtained as a result of the multiplexing are output to the TLV multiplexing device 70 of the same system.

(TLV multiplexing device)
FIG. 5 is a block diagram showing a configuration example of the TLV multiplexing device 70. The TLV multiplexing device 70 detects the MMTP packet corresponding to the switching point between the main system and the redundant system from the MMTP packet output from the IP multiplexing device 60 of the same system, and converts the MMTP packet into a TLV packet. , A device for generating a TLV packet corresponding to a detected switching point. Hereinafter, the configuration of such a TLV multiplexing device 70 will be described.

The TLV multiplexing devices 70 (# 1) and 70 (# 2) both have the same configuration, and MMTP packets / IP packets (for example, MMTP of video signals) output from the IP multiplexing device 60 of the same system. It corresponds to a packet / IP packet, an MMTP packet / IP packet of a voice signal, an MMTP packet / IP packet of a subtitle, etc., and these are encrypted when the scrambler 50 is provided). It is converted into the TLV transmission format (TLV packet) of the above, and the TLV packet obtained by the conversion is output to the redundant switching device 90. In addition, TLV-SI is internally generated.

In order to realize this, the TLV multiplexing device 70 includes a receiving unit 71, a filter unit 72, a sequence number acquisition unit 73, a switching point detecting unit 74, and a switching point detecting unit 74, which are provided for each type of input MMTP packet / IP packet. A TLV packetizing unit 77 is provided. Further, a switching control reception unit 75, a multiplexing unit 76, a TLV-SI generation unit 78, a null packet generation unit 79, and a transmission unit 81 are each provided.

The receiving units 71 (# 1), ..., 71 (# n) are provided for each type of MMTP packet / IP packet input to the TLV multiplexing device 70. For example, the receiving unit 71 (# 1) ) Receives the MMTP packet / IP packet of the video signal output from the IP multiplexing device 60, and the receiving unit 71 (# 2) receives the MMTP packet / IP packet of the voice signal output from the encoding device 20. The unit 71 (#n) receives the MMTP packet / IP packet of the electronic program guide output from the EPG (not shown), and outputs the MMTP packet / IP packet to the corresponding filter unit 72.

The filter units 72 (# 1), ..., 72 (# n) are provided corresponding to the receiving units 71 (# 1), ..., 71 (# n), respectively. For example, the filter unit is provided. 72 (# 1) filters the MMTP packet / IP packet of the video signal output from the receiving unit 71 (# 1), and the filtering unit 72 (# 2) performs the filtering process on the receiving unit 71 (# 2). The MMTP packet / IP packet of the voice signal output from is filtered, and the filter unit 72 (# n) is used as the MMTP packet / IP packet of the electronic program guide output from the receiving unit 71 (# n). It is filtered. Then, the filtered MMTP packet / IP packet is output to the corresponding sequence number acquisition unit 73.

The sequence number acquisition units 73 (# 1), ..., 73 (#n) are provided corresponding to the filter units 72 (# 1), ..., 72 (#n), respectively. The MMTP packet / IP packet output from the corresponding filter unit 72 is output to the corresponding switching point detection unit 74, and the MMTP packet among the MMTP packet / IP packet output from the corresponding filter unit 72 (FIG. 3). The MPU sequence number is acquired from the MTTP payload (see FIG. 4) included in (see), and the acquired MPU sequence number is output to the corresponding switching point detection unit 74.

The switching control receiving unit 75 receives a request for switching between the main system and the redundant system from the external input device 100. Then, when the switching control receiving unit 75 receives the switching request, the TLV multiplexing device 70 executes the process described later.

The switching point detection units 74 (# 1), ..., 74 (#n) are provided corresponding to the sequence number acquisition units 73 (# 1), ..., 73 (#n), respectively. The MMTP packet / IP packet output from the corresponding sequence number acquisition unit 73 is output to the corresponding TLV packetization unit 77, and the sequence number output from the corresponding sequence number acquisition unit 73 is a predetermined value. (For example, 0) is detected. For example, the switching point detection unit 74 (# 1) detects that the sequence number output from the sequence number acquisition unit 73 (# 1) has reached a predetermined value (for example, 0). Similarly, the switching point detection unit 74 (# 2) detects that the sequence number output from the sequence number acquisition unit 73 (# 2) has reached a predetermined value (for example, 0), and detects the switching point. The unit 74 (# 3) detects that the sequence number output from the sequence number acquisition unit 73 (# 3) has reached a predetermined value (for example, 0), and the switching point detection unit 74 (# n) Detects that the sequence number output from the sequence number acquisition unit 73 (# n) has reached a predetermined value (for example, 0). In this way, each switching point detection unit 74 detects the MMTP packet / IP packet corresponding to the switching point between the main system and the redundant system. Then, the detection result is output to the null packet generation unit 79.

The TLV packetizing units 77 (# 1), ..., 77 (# n) are provided corresponding to the switching point detection units 74 (# 1), ..., 74 (# n), respectively. Each of them inputs the MMTP packet / IP packet output by the corresponding switching point detection unit 74 to generate a TLV packet, and outputs the generated TLV packet to the multiplexing unit 76.

The TLV-SI generation unit 78 generates the TLV-SI and outputs it to the multiplexing unit 76.

The null packet generation unit 79 is an MMTP packet / IP packet corresponding to the switching point based on the detection results output from the switching point detection units 74 (# 1), (# 2), ..., (# N). Is output to the multiplexing unit 76 as a request signal for setting as a null packet. The request signal includes identification information of the MMTP packet / IP packet corresponding to the switching point.

The multiplexing unit 76 corresponds to the MMTP packet / IP corresponding to the identification information based on the identification information included in the request signal output from the null packet generation unit 79 for the TLV packet output from each TLV packetization unit 77. After setting the packet type of the TLV packet corresponding to the packet to a null packet, the multiplexed MMTP packet / IP packet is output to the transmission unit 81.

FIG. 6 is a diagram showing the structure of a TLV packet defined by ARIB STD-B32.

The “packet type” in FIG. 6 is an area used for identifying the type of packet stored in the TLV packet, and its allocation is as shown in FIG. 7. The "data length" is an area for writing the number of data bytes that follow it.

FIG. 7 is a diagram showing the assignment of “packet type” in the TLV packet defined by ARIB STD-B32.

Therefore, in the TLV packet having the structure as shown in FIG. 6, by setting the "packet type" to 0xFF, it becomes a null packet. In this way, the multiplexing unit 76 inserts the TLV packet of the packet type 0xFF corresponding to the switching point into the TLV packet corresponding to the MMTP packet / IP packet corresponding to the identification information.

After that, the transmission unit 81 outputs the TLV packet to the redundant switching device 90. Therefore, among the TLV packets output to the redundant switching device 90, the TLV packet corresponding to the switching point is a null packet.

The null packet generation unit 79 can generate a TLV packet corresponding to the switching point by doing the following instead of making it a null packet. That is, as shown in FIG. 7, 0x04 to 0xFD of the "packet type" are currently undefined. Therefore, any one of 0x04 to 0xFD of the "packet type" is newly assigned as the "switching point packet" indicating the switching point. For example, the case where the "packet type" is 0x04 is defined as a "switching point packet", and the multiplexing unit 76 outputs a packet output from the null packet generation unit 79 with respect to the TLV packet output from the TLV packetization unit 77. Insert a TLV packet of type 0x04.

After that, the transmission unit 81 outputs the TLV packet to the redundant switching device 90. In this case, among the TLV packets output to the redundant switching device 90, the TLV packet corresponding to the switching point becomes the "switching point packet".

(Redundant switching device)
FIG. 8 is a block diagram showing a configuration example of the redundant switching device 90.

The redundant switching device 90 is a device for switching between the main system and the redundant system, and is a switching control reception unit 91, a packet detection unit 92 (# 1), 92 (# 2), a packet identification unit 94, and the like. And a system switching unit 95 is provided.

The switching control receiving unit 91 receives a request for switching between the main system and the redundant system from the external input device 100. Then, when the switching control receiving unit 91 receives the switching request, the redundant switching device 90 executes the switching process as described below.

The packet detection unit 92 (# 1) is connected to the main system. That is, it is connected to the TLV multiplexing device 70 (# 1), detects the TLV packet output from the TLV multiplexing device 70 (# 1), and uses the detected TLV packet as the packet identification unit 94 and the system switching unit. Output to 95. Similarly, the packet detection unit 92 (# 2) connected to the redundant system detects the TLV packet output from the TLV multiplexing device 70 (# 2), and transmits the detected TLV packet to the packet identification unit 94 and the packet identification unit 94. Output to the system switching unit 95.

The packet identification unit 94 identifies a predetermined TLV packet from the TLV packets output from the packet detection units 92 (# 1) and 92 (# 2). The predetermined TLV packet is, for example, a null packet or a packet defined as a "switching point packet" as described above.

The packet identification unit 94 is like a TLV packet which is a null packet or a TLV packet defined as a "switching point packet" from the TLV packet output from the packet detection units 92 (# 1) and 92 (# 2). To identify a given TLV packet. Then, the identification result of the TLV packet is output to the system switching unit 95.

The system switching unit 95 sets the TLV packet output from the packet detection units 92 (# 1) and 92 (# 2) as the main system based on the identification result of the TLV packet output from the packet identification unit 94. Switch to a redundant system.

In this way, the redundant switching device 90 realizes seamless switching of TLV packets between the main system and the redundant system without analyzing the data.

(Overall operation of transmission system)
Next, the operation of the transmission system having the configuration as shown in FIG. 1 will be described with reference to the flowcharts of FIGS. 9 to 11.

A video signal, an audio signal, and a subtitle signal are input to the main encoding device 20 (# 1), for example, from a broadcasting master system (not shown). Similarly, a video signal, an audio signal, and a subtitle signal are input to the redundant coding device 20 (# 2) from, for example, a broadcast master system (not shown) (S1).

These signals are received by the signal coding unit 23, and the signal coding unit 23 encodes (compresses) these received signals, respectively, and switches between the encoded video signal, audio signal, and subtitle signal. It is output to the information setting unit 24 and the MMTP packetization unit 25, respectively.

In such a state, when the switching control receiving unit 21 receives the switching request from the external input device 100 (S2), the coding device 20 executes the switching process as described below. ..

First, the GOP phase adjustment unit 22 generates an adjustment signal for aligning the GOP phases of the video signal, the audio signal, and the subtitle signal, and outputs the adjustment signal to the switching information setting unit 24 (S3).

In the switching information setting unit 24, a predetermined value (for example, for example) is set in the MPU sequence number (FIG. 4) included in the MMTP packet (FIG. 3) corresponding to the switching point between the main system and the redundant system determined based on the adjustment signal. , 0) is generated (S4). This instruction input is output from the switching information setting unit 24 to the MMTP packetization unit 25.

Alternatively, the switching information setting unit 24 sets the least significant bit of the time stamp field (FIG. 3) included in the MMTP packet corresponding to the switching point between the main system and the redundant system determined based on the adjustment signal to a predetermined value. An instruction input for setting (for example, 0) is generated. Also in this case, the generated instruction input is output to the MMTP packetizing unit 25.

In the MMTP packetization unit 25, the MMTP packets of the video signal, the audio signal, and the subtitle signal are output to the MMT multiplexing device 30 in a state where the switching points can be identified (S6).

In each of the MMT multiplexing devices 30 (# 1) and 30 (# 2), the MMTP packet (for example, the MMTP packet of the video signal) output by the corresponding coding devices 20 (# 1) and 20 (# 2) is used. , MMTP packet of voice signal, MMTP packet of subtitles) and MMTP packet format data output from EPG (electronic program guide) transmission device (not shown) are multiplexed, and the multiplexed MMTP packet is of the same system. It is output to the scrambler 50 (S7).

In the scrambler 50 (# 1) and 50 (# 2), the MMTP packet output from the corresponding MMT multiplexing devices 30 (# 1) and 30 (# 2) is encrypted for copyright protection. The encrypted and encrypted MMTP packet is output to the IP multiplexing device 60 of the same system (S8).

In the IP multiplexing devices 60 (# 1) and 60 (# 2), the MMTP packets output from the corresponding scramblers 50 (# 1) and 50 (# 2) are IP packets from other devices (not shown). It is multiplexed with the data in the format (S9). Then, the MMTP packet / IP packet obtained as a result of the multiplexing is output to the TLV multiplexing device 70 of the same system.

In the TLV multiplexing devices 70 (# 1) and 70 (# 2), the receiving unit 71 (# 1) in which the MMTP packet / IP packet output from the IP multiplexing device 60 of the same system is provided for each signal type is provided. ), ..., 71 (# n), and output to the corresponding filter units 72 (# 1), ..., 72 (# n), respectively. Then, each filter unit 72 (# 1), ..., 72 (# n) filters and the filtered MMTP packet / IP packet is output to the corresponding sequence number acquisition unit 73 (S10). ).

In each sequence number acquisition unit 73 (# 1), ..., 73 (# n), the MMTP packet / IP packet output from the corresponding filter unit 72 is output to the corresponding switching point detection unit 74, respectively. .. Further, the MPU sequence number is acquired from the MTTP payload (see FIG. 4) included in the MMTP packet (see FIG. 3) among the MMTP packets / IP packets output from the corresponding filter unit 72, and the corresponding switching inspections are performed. It is output to the output portion 74 (S11).

The switching control receiving unit 75 receives a request for switching between the main system and the redundant system from the external input device 100. Then, when the switching control receiving unit 75 receives the switching request (S12), in each switching point detection unit 74 (# 1), ..., 74 (#n), the corresponding sequence number acquisition unit 73 The output MMTP packet / IP packet is output to the corresponding TLV packetization unit 77. Further, it is detected that the sequence number output from the corresponding sequence number acquisition unit 73 has reached a predetermined value (for example, 0), and the detection result is output to the null packet generation unit 79 (S13).

The TLV packetization unit 77 generates a TLV packet from the MMTP packet, and the generated TLV packet is output to the multiplexing unit 76 (S14).

The TLV-SI generation unit 78 generates the TLV-SI and outputs it to the multiplexing unit 76. Further, the null packet generation unit 79 nulls the MMTP packet / IP packet corresponding to the switching point based on the detection results output from the switching point detection units 74 (# 1), ..., 74 (# n). A request signal for setting as a packet is output to the multiplexing unit 76. The request signal includes identification information of the MMTP packet corresponding to the switching point.

In the multiplexing unit 76, for the TLV packet output from each TLV packetization unit 77, the MMTP / IP packet corresponding to the identification information is based on the identification information included in the request signal output from the null packet generation unit 79. The packet type of the TLV packet corresponding to is set to null packet, and the multiplexed MMTP / IP packet is output to the transmission unit 81. This MMTP / IP packet is output from the transmission unit 81 to the redundant switching device 90 (S15). As a result, among the TLV packets output to the redundant switching device 90, the TLV packet corresponding to the switching point becomes a null packet.

In addition, the multiplexing unit 76 newly allocates any one of 0x04 to 0xFD of the "packet type" which is currently undefined as a "switching point packet" indicating a switching point, and the null packet generation unit 79 The packet type of the corresponding TLV packet may be set to 0x04 based on the identification information included in the output request signal. As a result, among the TLV packets output to the redundant switching device 90, the TLV packet corresponding to the switching point is referred to as a “switching point packet”.

In the redundant switching device 90, when the switching control receiving unit 91 receives a request for switching between the main system and the redundant system from the external input device 100 (S16), the redundant switching device 90 operates as follows.

That is, the TLV packet output from the main system TLV multiplexing device 70 (# 1) is detected by the packet detection unit 92 (# 1), and the detected TLV packet is the packet identification unit 94 and the system switching unit. It is output to 95. Further, the TLV packet output from the redundant TLV multiplexing device 70 (# 2) is detected by the packet detection unit 92 (# 2), and the detected TLV packet is the packet identification unit 94 and the system switching unit. It is output to 95 (S17).

The packet identification unit 94 identifies a TLV packet having a predetermined multiplex configuration from the TLV packets output from the packet detection units 92 (# 1) and 92 (# 2) (S18). The TLV packet having a predetermined multiplex configuration is, for example, a null packet or a packet defined as a "switching point packet" as described above.

As described above, in the packet identification unit 94, the TLV packets output from the packet detection units 92 (# 1) and 92 (# 2) are defined as null packets or "switching point packets". A TLV packet having a predetermined multiplex configuration, such as a TLV packet, is identified. Then, the identified TLV packet is output to the system switching unit 95.

The system switching unit 95 switches between the main system and the redundant system in the TLV packet output from the packet identification unit 94 with respect to the TLV packet output from the packet detection units 92 (# 1) and 92 (# 2). Is carried out (S19).

In this way, the redundant switching device 90 realizes seamless switching of TLV packets between the main system and the redundant system without analyzing the data.

As described above, according to the transmission system to which the transmission method of the present embodiment is applied, the TLV multiplexing device 70 makes it possible to identify the switching point of the TLV packet between the main system and the redundant system. As a result, the redundant switching device 90 can seamlessly switch the TLV packet between the main system and the redundant system without analyzing data such as video and audio.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, as well as in the scope of the invention described in the claims and the equivalent scope thereof.

10 Packet transmission system, 20 Encoding device, 21 Switching control reception unit, 22 GOP phase adjustment unit, 23 Signal coding unit, 24 Switching information setting unit, 25 MMTP packetization unit, 30 MMT multiplexing device, 50 scrambler, 60 IP multiplexing device, 70 TLV multiplexing device, 71 receiving unit, 72 filtering unit, 73 sequence number acquisition unit, 74 switching point detection unit, 75 switching control receiving unit, 76 multiplexing unit, 77 TLV packetizing unit, 78 TLV -SI generator, 79 null packet generator, 81 transmitter, 90 redundant switching device, 91 switching control reception unit, 92 packet detection unit, 94 packet identification unit, 95 system switching unit, 100 external input device.

Claims (5)

A multiplexing device applied to a transmission system having a main system and a redundant system for transmitting TLV packets, and provided in each of the main system and the redundant system.
A detection unit that detects a switching point MMTP packet corresponding to a switching point between the main system and the redundant system from the MMTP (MPEG Media Transport Protocol) packet converted into the TLV packet.
A packetizing unit that generates the TLV packet from the MMTP packet, and
A packet generation unit that generates a TLV packet corresponding to the switching point by allocating any of the undefined packet types in the TLV packet as the switching point MMTP packet.
A multiplexing device equipped with. The first aspect of claim 1, further comprising a multiplexing unit for inserting a TLV packet of the packet type assigned as the switching point MMTP packet by the packet generation unit into the TLV packet generated by the packetization unit. Multiplexing device. It is a switching device applied to a transmission system including a main system and a redundant system for transmitting TLV packets, and for switching between the main system and the redundant system.
A detector that detects the input TLV packet and
An identification unit that identifies a switching point MMTP packet to which any of the packet types undefined in the TLV packet is assigned from the TLV packet detected by the detection unit.
A switching unit that switches between the main system and the redundant system based on the identification result of the identification unit for the TLV packet detected by the detection unit.
A switching device equipped with. A transmission system equipped with a main system and a redundant system for transmitting TLV packets.
The multiplexing device provided in each of the main system and the redundant system, and
A switching device for switching between the main system and the redundant system is provided.
The multiplexing device is
A first detection unit that detects a switching point MMTP packet corresponding to a switching point between the main system and the redundant system from the MMTP (MPEG Media Transport Protocol) packet converted into the TLV packet.
A packetizing unit that generates the TLV packet from the MMTP packet, and
A packet generation unit that generates a TLV packet corresponding to the switching point by allocating any of the undefined packet types in the TLV packet as the switching point MMTP packet.
A multiplex unit that inserts a packet type TLV packet assigned as the switching point MMTP packet by the packet generation unit into the TLV packet generated by the packetization unit.
A transmission unit that outputs a TLV packet from the multiplex unit to the switching device is provided.
The switching device is
A second detection unit that detects the TLV packet output from the transmission unit, and
An identification unit that identifies the switching point MMTP packet from the TLV packet detected by the second detection unit, and
A transmission system including a switching unit that switches between the main system and the redundant system in the switching point MMTP packet with respect to the TLV packet from the second detection unit. A transmission method applied to a transmission system having a main system and a redundant system for transmitting TLV packets.
In the multiplexing device provided in each of the main system and the redundant system,
From the MMTP (MPEG Media Transport Protocol) packet converted into the TLV packet, the switching point MMTP packet corresponding to the switching point between the main system and the redundant system is detected.
The TLV packet is generated from the MMTP packet,
By assigning any of the packet types undefined in the TLV packet as the switching point MMTP packet, a TLV packet corresponding to the switching point is generated.
A TLV packet of the packet type assigned as the switching point MMTP packet is inserted into the generated TLV packet and output to the switching device.
In the switching device for switching between the main system and the redundant system,
The output TLV packet is detected and
The switching point MMTP packet is identified from the detected TLV packet, and the switching point MMTP packet is identified.
A transmission method in which the detected TLV packet is switched between the main system and the redundant system in the switching point MMTP packet.

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