WO2015040817A1 - Transmission method, reception method, transmitter apparatus, and receiver apparatus - Google Patents

Abstract

　A transmission method in content communication using an Internet Protocol (IP) packet performed through broadcasting, the transmission method including a generation step (S151) for generating a communication frame for storing a plurality of second communication units each storing one or more first communication units in which the IP packet is stored, and a transmission step (S152) for transmitting the generated frame, the generation step (S151) including, in the first communication unit located at the beginning inside the frame, reference clock information indicating a time of day needed for content reproduction on the receiving side. There is thereby provided a transmission method capable of reducing a process for acquiring the reference clock information on the receiving side.

Description

Transmission method, reception method, transmission device, and reception device

The present disclosure relates to a transmission method and a reception method in a case where content is transmitted through broadcasting using an IP (Internet Protocol) packet.

The MMT method (see Non-Patent Document 1) is a multiplexing method for multiplexing and packetizing content such as video and audio and transmitting the content through one or more transmission paths such as broadcasting or communication. When the MMT method is applied to a broadcasting system, the reference clock information on the transmission side is transmitted to the reception side, and the reception device generates a system clock in the reception device based on the reference clock information.

A transmission method according to an aspect of the present disclosure is a transmission method in content transmission using an IP (Internet Protocol) packet performed through broadcasting, and stores one or more first transmission units in which the IP packet is stored. A generation step of generating a transmission frame storing a plurality of second transmission units, and a transmission step of transmitting the generated frame. In the generation step, the first second in the frame Reference clock information indicating the time for reproducing the content is included in the first transmission unit located at the head of the transmission unit.

Note that these comprehensive or specific aspects may be realized by a recording medium such as a system, an apparatus, a method, an integrated circuit, a computer program, or a computer-readable CD-ROM. These comprehensive or specific aspects may be realized by any combination of a system, an apparatus, a method, an integrated circuit, a computer program, and a recording medium.

According to the transmission method and the reception method according to an aspect of the present disclosure, it is possible to reduce processing for acquiring reference clock information on the reception side.

FIG. 1 is a protocol stack diagram when transmission is performed using the MMT scheme and the advanced BS transmission scheme. FIG. 2 is a diagram illustrating a data structure of a TLV packet. FIG. 3 is a block diagram showing a basic configuration of the receiving apparatus. FIG. 4 is a block diagram showing a functional configuration of the receiving apparatus when the reference clock information is stored in the extension field of the MMT packet header. FIG. 5 is a diagram illustrating a flow of obtaining reference clock information of the receiving apparatus when the reference clock information is stored in the extension field of the MMT packet header. FIG. 6 is a block diagram illustrating a functional configuration of the receiving device when the reference clock information is stored in the control information. FIG. 7 is a diagram illustrating an acquisition flow of the reference clock information of the receiving device when the reference clock information is stored in the control information. FIG. 8 is a block diagram showing a configuration of a receiving apparatus when reference clock information is stored in a TLV packet. FIG. 9 is a diagram illustrating an example in which the long format NTP is stored in the TLV packet. FIG. 10 is a diagram illustrating an acquisition flow of the reference clock information of the receiving device when the reference clock information is stored in the TLV packet. FIG. 11 is a diagram illustrating a configuration in which the reference clock information is added immediately before the header of the IP packet. FIG. 12 is a diagram illustrating a configuration in which the reference clock information is added immediately before the TLV packet. FIG. 13 is a diagram illustrating a configuration of a transmission slot. FIG. 14 is a diagram illustrating a configuration of a slot header of a transmission slot. FIG. 15 is a block diagram illustrating a functional configuration of the receiving apparatus when information indicating that the reference clock information is included in the slot header is stored in the TMCC control information. FIG. 16 is a diagram showing an acquisition flow of the reference clock information when information indicating that the reference clock information is included in the slot header is stored in the TMCC control information. FIG. 17 is a diagram showing a flow when a bit string at a specific position is extracted from an IP packet or a compressed IP packet. FIG. 18 is a block diagram illustrating a functional configuration of the transmission apparatus. FIG. 19 is a diagram illustrating an operation flow of the transmission apparatus.

(Knowledge that became the basis of this disclosure)
The present disclosure relates to a hybrid distribution system that uses an MMT (MPEG Media Transport) method being standardized by MPEG (Moving Picture Expert Group), transmits reference clock information from a transmission side, and receives reference clock information on a reception side. The present invention relates to a method and an apparatus for generating (reproducing) a reference clock.

The MMT method is a multiplexing method for multiplexing and packetizing video and audio and transmitting them through one or more transmission paths such as broadcasting or communication.

When the MMT method is applied to a broadcasting system, the reference clock on the transmission side is synchronized with NTP (Network Time Protocol) defined in IETF RFC 5905, and based on the reference clock, PTS (Presentation Time Stamp) or DTS (Decode) Give the media a time stamp such as Time Stamp. Further, the reference clock information on the transmission side is transmitted to the reception side, and the reception device generates a reference clock (hereinafter also referred to as a system clock) in the reception device based on the reference clock information.

In a broadcasting system, it is desirable to use a 64-bit long format NTP that can indicate an absolute time as reference clock information. However, in the conventional MMT system, it is stipulated that 32-bit short format NTP is stored and transmitted in the MMT packet header, but transmission of long format NTP is not stipulated. Accurate reference clock information cannot be acquired.

On the other hand, it is possible to define a long format NTP as control information such as a message, a table, or a descriptor, and transmit the control information with an MMT packet header added. In this case, the MMT packet is transmitted through a broadcast transmission path or a communication transmission path by being stored in an IP packet.

When transmitting an MMT packet using the advanced BS transmission system defined by the ARIB standard, the MMT packet is encapsulated into an IP packet, the IP packet is encapsulated into a TLV (Type Length Value) packet, and then the advanced BS transmission system is used. Store in the specified transmission slot.

However, when the reference clock information is stored in the layer of the MMT packet on the transmission side, in order to obtain the reference clock information on the reception side, the TLV packet is extracted from the transmission slot, the IP packet is extracted from the TLV packet, and the IP packet Multiple processes such as extracting the MMT packet from the MMT packet and further extracting the reference clock information from the header or payload of the MMT packet, and there are many processes for acquiring the reference clock information, and more time is required until the acquisition. Cost.

In addition, the processing in the IP layer and higher layers is generally software processing. When the reference clock information is stored in the MMT packet, the reference clock information is extracted and reproduced by the software program. In this case, there is a problem that jitter is generated in the acquired reference clock information due to the processing capability of the CPU, interrupts and priorities from other software programs, and the like.

Therefore, a transmission method according to an aspect of the present disclosure is a transmission method in content transmission using an IP (Internet Protocol) packet performed through broadcasting, and the first transmission unit in which the IP packet is stored is 1 A generation step of generating a transmission frame storing a plurality of the second transmission units stored as described above; and a transmission step of transmitting the generated frame. In the generation step, Reference clock information indicating the time for reproducing the content is included in the first transmission unit positioned at the head in the second transmission unit.

Thus, by including the reference clock information in the TLV packet located at the head in the transmission slot, the receiving apparatus can specify the position of the reference clock information in advance. Therefore, the receiving apparatus can reduce (simplify) the process of acquiring the reference clock information. An example of the first transmission unit is a TLV packet, an example of the second transmission unit is a slot, and an example of a transmission frame is a transmission slot.

Also, the first transmission unit may be a variable-length transmission unit, and the second transmission unit may be a fixed-length transmission unit.

Further, the IP packet stored in the first transmission unit located at the head may be an IP packet not subjected to header compression.

In this way, by specifying the presence or absence of IP packet header compression on the transmission side, the position of the reference clock information can be specified in more detail on the reception side. Therefore, it is possible to simplify the process in which the receiving device acquires the reference clock information.

Further, the first transmission unit is a TLV (Type Length Value) packet, the second transmission unit is a slot in the advanced BS transmission system, and the frame is a transmission slot in the advanced BS transmission system. May be.

The reference clock information may be NTP (Network Time Protocol).

In the transmission step, the frame may be transmitted at a predetermined transmission cycle.

A reception method according to an aspect of the present disclosure is a reception method in content transmission using an IP packet performed through broadcasting, and includes a second transmission unit including one or more first transmission units in which the IP packet is stored. A receiving step for receiving a frame for transmission in which a plurality of transmission units are stored, wherein the first transmission unit located at the head of the second transmission unit at the head of the frame includes reference clock information; And extracting the reference clock information from the received frame, and generating a clock for reproducing the content using the extracted reference clock information.

A transmission apparatus according to an aspect of the present disclosure is a transmission apparatus used for content transmission using IP packets performed through broadcasting, and stores one or more first transmission units in which the IP packets are stored A generation unit configured to generate a transmission frame storing a plurality of second transmission units; and a transmission unit configured to transmit the generated frame, wherein the generation unit includes a first second transmission unit in the frame. In the first transmission unit located at the top of the reference information, reference clock information indicating the time for reproducing the content is included on the receiving side.

A receiving apparatus according to an aspect of the present disclosure is a receiving apparatus used for content transmission using an IP packet performed through broadcasting, and includes a first transmission unit in which at least one first transmission unit is stored. Reception for receiving a frame containing a plurality of transmission units 2 and including reference clock information in the first transmission unit located at the head of the second transmission unit at the head of the frame An extraction unit that extracts the reference clock information from the received frame, and a generation unit that generates a clock for reproducing the content using the extracted reference clock information.

Note that these comprehensive or specific aspects may be realized by a recording medium such as a system, an apparatus, a method, an integrated circuit, a computer program, or a computer-readable CD-ROM. These comprehensive or specific aspects may be realized by any combination of a system, an apparatus, a method, an integrated circuit, a computer program, and a recording medium.

(Embodiment 1)
[Basic configuration of MMT system]
First, a basic configuration of the MMT method will be described. FIG. 1 shows a protocol stack diagram when transmission is performed using the MMT scheme and the advanced BS transmission scheme.

In the MMT method, information such as video and audio is stored in a plurality of MPUs (Media Presentation Units) and a plurality of MFUs (Media Fragment Units), and an MMT packet header is added to form an MMT packet.

On the other hand, in the MMT system, an MMT packet header is also attached to control information such as an MMT message to form an MMT packet. The MMT packet header is provided with a field for storing NTP in a 32-bit short format, and this field can be used for QoS control of a communication line.

The MMT packetized data is encapsulated in an IP packet having a UDP header or an IP header. At this time, when a set of packets having the same source IP address, destination IP address, source port number, destination port number, and protocol type in the IP header or UDP header is defined as an IP data flow, The plurality of IP packets included have redundant headers. For this reason, in one IP data flow, some IP packets are header-compressed.

Next, the TLV packet will be described in detail. FIG. 2 is a diagram illustrating a data structure of a TLV packet.

As shown in FIG. 2, the TLV packet stores an IPv4 packet, an IPv6 packet, a compressed IP packet, a NULL packet, and a transmission control signal. These pieces of information are identified using an 8-bit data type. Transmission control signals include, for example, AMT (Address Map Table) and NIT (Network Information Table). In the TLV packet, a 16-bit field is used to indicate the data length (in bytes), and then the data value is stored. Since there is 1-byte header information before the data type (not shown in FIG. 2), the TLV packet has a total header area of 4 bytes.

A TLV packet is mapped to a transmission slot in the advanced BS transmission system, and pointers indicating the beginning position of the first packet and the end position of the last packet included in each slot in TMCC (Transmission and Multiplexing Configuration Control) control information / Slot information is stored.

Next, the configuration of the receiving apparatus when transmitting the MMT packet using the advanced BS transmission method will be described. FIG. 3 is a block diagram showing a basic configuration of the receiving apparatus. Note that the configuration of the receiving apparatus in FIG. 3 is simplified, and a more specific configuration will be described later separately according to the manner in which the reference clock information is stored.

The receiving device 20 includes a receiving unit 10, a decoding unit 11, a TLV demultiplexer (DEMUX) 12, an IP demultiplexer (DEMUX) 13, and an MMT demultiplexer (DEMUX) 14.

The receiving unit 10 receives transmission path encoded data.

The decoding unit 11 decodes the transmission path encoded data received by the receiving unit 10, performs error correction, and extracts a TMCC control signal and TLV data. The TLV data extracted by the decoding unit 11 is subjected to DEMUX processing by the TLV demultiplexer 12.

The DEMUX process of the TLV demultiplexer 12 differs depending on the data type. For example, when the data type is a compressed IP packet, the TLV demultiplexer 12 performs processing such as restoring the compressed header and passing it to the IP layer.

The IP demultiplexer 13 performs processing such as header analysis of IP packets or UDP packets, and extracts MMT packets for each IP data flow.

The MMT demultiplexer 14 performs a filtering process (MMT packet filtering) based on the packet ID stored in the MMT packet header.

[Method for storing reference clock information in MMT packet]
In the MMT system described with reference to FIGS. 1 to 3, a 32-bit short format NTP can be stored and transmitted in the MMT packet header, but there is no method for transmitting the long format NTP.

Hereinafter, a method for storing the reference clock information in the MMT packet will be described. First, a method for storing the reference clock information in the MMT packet will be described.

When a descriptor, a table, or a message for storing reference clock information is defined and stored in an MMT packet as control information, a descriptor, a table indicating reference clock information, or an identifier indicating a message is control information. Shown in The control information is stored in the MMT packet on the transmission side.

Thereby, the receiving device 20 can identify the reference clock information based on the identifier. Note that the reference clock information may be stored in the MMT packet by using an existing descriptor (for example, CRI_descriptor ()).

Next, a method for storing the reference clock information in the MMT packet header will be described.

For example, there is a method of storing using a header_extension field (hereinafter referred to as an extension field). The extension field is enabled by setting the extension_flag of the MMT packet header to “1”.

In the extension field, an extension field type indicating the data type of data stored in the extension field is stored, and in the extension field type, information indicating reference clock information (for example, 64-bit long format NTP) is stored. There is a method of storing the reference clock information in the extension field.

In this case, when the header_extension_flag of the MMT packet header is “1”, the receiving device 20 refers to the extension field of the MMT packet. If the extended field type indicates that it is reference clock information, the reference clock information is extracted and the clock is reproduced.

Note that the reference clock information may be stored in an existing header field. Further, when there are unused fields or when there are fields that are not necessary for broadcasting, the reference clock information may be stored in these fields.

Also, the reference clock information may be stored using both the existing field and the extension field. For example, an existing 32-bit short format NTP field and an extension field may be used in combination.

In order to maintain compatibility with the existing field, only the 32-bit portion corresponding to the short format format among the 64-bit long format NTP may be stored in the existing field, and the remaining 32 bits may be stored in the extension field.

The reference clock information is, for example, the time when the first bit of the MMT packet in which the reference clock information is stored passes through a predetermined position (for example, when output from a specific component of the transmission apparatus). However, the time when a bit at another position passes a predetermined position may be used.

When the reference clock information is stored in the MMT packet as control information, the MMT packet including the control information is transmitted at a predetermined transmission interval.

When the reference clock information is stored in the extension field of the MMT packet, it is stored in the extension field of the header of the predetermined MMT packet. Specifically, for example, at least one reference clock information is stored in the header extension field of the MMT packet at intervals of 100 ms.

When the reference clock information is stored in the MMT packet, the program information stores the packet ID of the MMT in which the reference clock information is stored. The receiving device 20 analyzes the program information and acquires an MMT packet in which the reference clock information is stored. At this time, the packet ID of the MMT packet storing the reference clock information may be defined in advance as a fixed value. Thereby, the receiving device 20 can acquire the reference clock information without analyzing the program information.

[Operation flow when reference clock information is stored in MMT packet]
Next, an operation flow (reference clock information acquisition flow) when the reference clock information is stored in the MMT packet will be described.

First, the acquisition flow of the reference clock information of the receiving device 20 when the reference clock information is stored in the extension field of the MMT packet header will be described. FIG. 4 is a block diagram illustrating a functional configuration of the reception device 20 when the reference clock information is stored in the extension field of the MMT packet header.

FIG. 5 is a diagram showing an acquisition flow of the reference clock information of the receiving device 20 when the reference clock information is stored in the extension field of the MMT packet header.

As shown in FIG. 4, when the reference clock information is stored in the extension field of the MMT packet header, the MMT demultiplexer 14 is provided with a reference clock information extraction unit 15 (an example of an extraction unit). A reference clock generation unit 16 (an example of a generation unit) is provided at the subsequent stage of the multiplexer 14.

5, the decoding unit 11 of the receiving device 20 decodes the transmission path encoded data received by the receiving unit 10 (S101), and extracts the TLV packet from the transmission slot (S102).

Next, the TLV demultiplexer 12 performs DEMUX on the extracted TLV packet and extracts an IP packet (S103). At this time, the header of the compressed IP packet is reproduced.

Next, the IP demultiplexer 13 demultiplexes the IP packet, acquires the designated IP data flow, and extracts the MMT packet (S104).

Next, the MMT demultiplexer 14 analyzes the header of the MMT packet and determines whether or not the extension field is used and whether or not there is reference clock information in the extension field (S106). If there is no reference clock information in the extension field (No in S106), the process is terminated.

On the other hand, when it is determined that there is reference clock information in the extension field (Yes in S106), the reference clock information extraction unit 15 extracts the reference clock information from the extension field (S107). Then, the reference clock generation unit 16 generates a system clock based on the extracted reference clock information (S108). In other words, the system clock is a clock for reproducing content.

Next, the reference clock information acquisition flow of the receiving device 20 when the reference clock information is stored in the control information will be described. FIG. 6 is a block diagram illustrating a functional configuration of the receiving device 20 when the reference clock information is stored in the control information. FIG. 7 is a diagram illustrating an acquisition flow of the reference clock information of the reception device 20 when the reference clock information is stored in the control information.

As shown in FIG. 6, when the reference clock information is stored in the control information, the reference clock information extraction unit 15 is arranged at the subsequent stage of the MMT demultiplexer 14.

In the flow of FIG. 7, the processing of step S111 to step S114 is the same as the flow of step S101 to step S104 described in FIG.

Subsequent to step S114, the MMT demultiplexer 14 acquires the packet ID of the packet including the reference clock information from the program information (S115), and acquires the MMT packet of the packet ID (S116). Subsequently, the reference clock information extraction unit 15 extracts the reference clock information from the control signal included in the extracted MMT packet (S117), and the reference clock generation unit 16 obtains the system clock based on the extracted reference clock information. Generate (S118).

[Method for storing reference clock information in TLV packet]
As described with reference to FIGS. 5 and 7, when the reference clock information is stored in the MMT packet, in order to obtain the reference clock information on the receiving side, the receiving apparatus 20 extracts the TLV packet from the transmission slot, and the TLV Extract the IP packet from the packet. Further, the receiving device 20 extracts the MMT packet from the IP packet, and further extracts the reference clock information from the header or payload of the MMT packet. As described above, when the reference clock information is stored in the MMT packet, there are many processes for acquiring the reference clock information, and more time is required for the acquisition.

Therefore, processing for assigning a time stamp to media such as video and audio based on the reference clock and processing for transmitting the media are realized using the MMT method, and transmission of the reference clock information is performed lower than the MMT layer. A method performed using a lower layer, a lower protocol, or a lower multiplexing scheme will be described.

First, a method for storing and transmitting reference clock information in a TLV packet will be described. FIG. 8 is a block diagram illustrating a configuration of the reception device 20 when the reference clock information is stored in the TLV packet.

8 is different from FIGS. 4 and 6 in the arrangement of the reference clock information extraction unit 15 and the reference clock generation unit 16. In FIG. 8, the synchronization unit 17 and the decryption presentation unit 18 are also illustrated.

As shown in FIG. 2, the TLV packet is composed of an 8-bit data type, a 16-bit data length, and 8 * N-bit data. As described above, a 1-byte header (not shown in FIG. 2) is present before the data type. The data type is specifically defined as, for example, 0x01: IPv4 packet, 0x03: header compressed IP packet, and the like.

In order to store new data in the TLV packet, the data type is defined using the undefined area of the data type. In order to indicate that the reference clock information is stored in the TLV packet, the data type is described to indicate that the data is the reference clock information.

Note that the data type may be defined for each type of reference clock. For example, data types indicating short format NTP, long format NTP, and PCR (Program Clock Reference) may be defined individually. FIG. 9 is a diagram illustrating an example in which the long format NTP is stored in the TLV packet, and the long format NTP is stored in the data field.

In this case, the reference clock information extraction unit 15 analyzes the data type of the TLV packet, and when the reference clock information is stored, analyzes the data length and extracts the reference clock information from the data field.

When the data length is uniquely determined by the data type, the reference clock information extraction unit 15 may acquire the reference clock information without analyzing the data length field. For example, when it is indicated that the data type is 64 bit long low mat NTP, the reference clock information extraction unit 15 may extract the 4th byte + 1 bit to the 4th byte + 64th bit. Further, the reference clock information extraction unit 15 may extract only desired bits from the 64-bit data.

Next, an operation flow (acquisition flow of reference clock information) of the receiving device 20 when the reference clock information is stored in the TLV packet will be described with reference to FIG. FIG. 10 is a diagram illustrating an acquisition flow of the reference clock information of the reception device 20 when the reference clock information is stored in the TLV packet.

In the flow of FIG. 10, first, the decoding unit 11 decodes the transmission path encoded data received by the receiving unit 10 (S121), and extracts the TLV packet from the transmission slot (S122).

Next, the TLV demultiplexer 12 analyzes the data type of the TLV packet (S123), and determines whether the data type is reference clock information (S124). When the data type is the reference clock (Yes in S124), the reference clock information extraction unit 15 extracts the reference clock information from the data field of the TLV packet (S125). Then, the reference clock generation unit 16 generates a system clock based on the reference clock information (S126). On the other hand, when the data type is not the reference clock information (No in S124), the reference clock information acquisition flow ends.

In the flow not shown, the IP demultiplexer 13 extracts the IP packet according to the data type. Then, the IP DEMUX process and the MMT DEMUX process are performed on the extracted IP packet to extract the MMT packet. Further, the synchronization unit 17 outputs the video data to the decoding presentation unit 18 at a timing when the time stamp of the video data included in the extracted MMT packet matches the reference clock generated in step S126, and the decoding presentation unit 18 Decodes and presents video data.

In the transmission method described above, it is indicated that the reference clock information is stored in the type data of the TLV packet, and the reference clock information is stored in the data field of the TLV packet. Thus, by storing and transmitting the reference clock information using a lower layer or lower protocol than the MMT layer, it is possible to reduce processing and time until the reference clock information is extracted in the receiving device 20. it can.

In addition, since the reference clock information can be extracted and reproduced in lower layers across the IP layer, the reference clock information can be extracted by hardware implementation. As a result, the influence of jitter and the like can be reduced as compared with the case where the extraction of the reference clock information is performed by software implementation, and a reference clock with higher accuracy can be generated.

Next, another method for storing the reference clock information will be described.

In the flow of FIG. 10 above, when the data length is uniquely determined by the data type, the data length field may not be transmitted. When the data length field is not transmitted, an identifier indicating that the data length field is data that is not transmitted is stored.

In the description of FIG. 10, the reference clock information is stored in the data field of the TLV packet. However, the reference clock information may be added immediately before or after the TLV packet. Further, the reference clock information may be added immediately before or after the data stored in the TLV packet. In these cases, a data type that can identify the location where the reference clock information is added is assigned.

For example, FIG. 11 is a diagram showing a configuration in which the reference clock information is added immediately before the header of the IP packet. In this case, the data type indicates an IP packet with reference clock information. When the data type indicates that the data type is an IP packet with reference clock information, the receiving device 20 (reference clock information extraction unit 15) sets a predetermined reference clock information length from the beginning of the data field of the TLV packet. By extracting the bits, reference clock information can be acquired. At this time, the data length may specify the length of data including the length of the reference clock information, or may specify the length not including the length of the reference clock information.

FIG. 12 is a diagram showing a configuration in which the reference clock information is added immediately before the TLV packet. In this case, the data type is a conventional data type, and an identifier indicating that the TLV packet is a TLV packet with reference clock information is stored in, for example, the slot header of the transmission slot or TMCC control information. FIG. 13 is a diagram illustrating a configuration of a transmission slot, and FIG. 14 is a diagram illustrating a configuration of a slot header of the transmission slot.

As shown in FIG. 13, the transmission slot is composed of a plurality of slots (in the example of FIG. 13, 120 slots of Slot # 1-Slot # 120). The number of bits included in each slot is a fixed number of bits uniquely determined based on the error correction coding rate, has a slot header, and stores one or more TLV packets. As shown in FIG. 13, the TLV packet has a variable length.

As shown in FIG. 14, in the first TLV indication field (16 bits) of the slot header, the position of the first byte of the first TLV packet in the slot is indicated by the number of bytes from the beginning of the slot excluding the slot header. Is stored. The remaining 160 bits of the slot header are undefined.

When an identifier indicating that the TLV packet is a TLV packet with reference clock information is stored in the slot header, for example, information that can specify the position of the TLV packet with reference clock information in the slot, the type of reference clock information, and data The length and the like are stored by extending (using) the undefined field of the slot header.

When an identifier indicating that the TLV packet is a TLV packet with reference clock information is stored in the TMCC control information, information on whether or not the reference clock information is included in the slot may be stored in the TMCC control information. As a data type stored in the slot, a data type indicating a TLV packet with reference clock information may be defined.

Also, an area for storing the reference clock information may be newly defined in the undefined field of the slot header.

Also, the reference clock information may be stored in a predetermined slot, or information indicating that the reference clock information is included in the slot header. Here, the predetermined slot is, for example, the first slot (Slot # 1 in the example of FIG. 13) of the transmission slots, and the reference clock stored in the IP packet in the first TLV packet in this slot. Information may be included.

Further, information indicating that the reference clock information is included in the TMCC control information may be stored. FIG. 15 is a block diagram illustrating a functional configuration of the reception device 20 when information indicating that the reference clock information is included in the slot header is stored in the TMCC control information. FIG. 16 is a diagram showing an acquisition flow of the reference clock information when information indicating that the reference clock information is included in the slot header is stored in the TMCC control information.

As shown in FIG. 15, in the receiving device 20 in the case where information indicating that the reference clock information is included in the slot header is stored in the TMCC control information, the reference clock information extraction unit 15 is connected to the decoding unit 11. A reference clock signal is obtained from the output transmission slot.

In the flow of FIG. 16, the decoding unit 11 decodes the transmission path encoded data (S131), analyzes the TMCC control signal (S132), and determines whether there is reference clock information in the slot header in the transmission slot. (S133). If there is reference clock information in the slot header (Yes in S133), the reference clock information extraction unit 15 extracts the reference clock information from the slot header (S134), and the reference clock generation unit 16 uses the reference clock information based on the reference clock information. A system reference clock (system clock) is generated (S135). On the other hand, if there is no reference clock information in the slot header (No in S133), the reference clock information acquisition flow ends.

Since such a receiving apparatus 20 can acquire the reference clock information at the layer of the transmission slot, it can acquire the reference clock information even earlier than the case where it is stored in the TLV packet.

As described above, by storing the reference clock information in the TLV packet or the transmission slot, it is possible to reduce the processing until the reference clock information is acquired in the receiving device 20, and the acquisition time of the reference clock information. Can be shortened.

In addition, since the reference clock information is stored in the physical layer in this way, acquisition and reproduction of the reference clock information by hardware can be easily realized, and a clock with higher accuracy than acquisition and reproduction of the reference clock information by software. Playback is possible.

In addition, the transmission method according to the first embodiment can be summarized as follows. In a system including a plurality of layers (protocols) including the IP layer, the time stamp of the media is obtained based on the reference clock information in a layer higher than the IP layer. And reference clock information is transmitted in a layer lower than the IP layer. According to such a configuration, it becomes easy for the receiving device 20 to process the reference clock information by hardware.

Note that, based on the same idea, it is conceivable to store the reference clock information in an IP packet that is not stored in the MMT packet. Even in such a case, the processing for obtaining the reference clock information can be reduced as compared with the case where the reference clock information is stored in the MMT packet.

[Reference clock information transmission cycle]
Hereinafter, a supplementary description will be given of the reference clock information transmission cycle.

When storing the reference clock information in the TLV packet, for example, the time at which the first bit of the TLV packet is transmitted on the transmission side is stored as the reference clock information. Further, a predetermined time other than the transmission time of the first bit may be stored as the reference clock information.

TLV packets including reference clock information are transmitted at predetermined intervals. In other words, the TLV packet including the reference clock information is included in the transmission slot and transmitted at a predetermined transmission cycle. For example, at least one reference clock information may be stored and transmitted in a TLV packet at 100 ms intervals.

Also, TLV packets including reference clock information may be arranged at predetermined intervals at predetermined locations in the transmission slot of the advanced BS transmission system. In addition, a TLV packet including reference clock information is stored once every 5 slot units, which is a slot allocation unit of the TLV packet, and the reference clock information is stored in the first TLV packet of the first slot among the 5 slot units. May be. That is, the TLV packet including the reference clock information may be arranged at the head of the head slot in the transmission slot (that is, immediately after the slot header).

Also, the transmission cycle and the transmission interval of the reference clock information may be changed according to the modulation scheme or coding rate of the transmission path coding scheme.

[How to get upper layer reference clock information quickly]
Next, a method for shortening the time until acquisition of the reference clock information by collectively processing DEMUX from the lower layer to the upper layer in the receiving device 20 will be described.

Here, a method for storing reference clock information in an upper layer such as an MMT packet and storing the MMT packet in which the reference clock information is stored in an IP packet will be described. In the method described below, by defining a protocol for storing an IP packet in which reference clock information is stored in a TLV packet, an MMT packet that is an upper layer is directly referenced from a lower layer such as a TLV packet. The reference clock information included in the MMT packet is acquired without performing normal DEMUX processing.

On the transmission side, the reference clock information is included in the control information stored in the MMT packet described above. A predetermined packet ID is assigned to the control information including the reference clock information. On the transmission side, the MMT packet including the reference clock information is stored in a dedicated IP data flow, and the transmission source IP address, destination IP address, transmission source port number, destination port number, and protocol are determined in advance. A type is given.

In the receiving apparatus 20 that has received the transmission line encoded data generated in this way, the TLV demultiplexer 12 can extract an IP packet including reference clock information by acquiring a predetermined IP data flow. .

When the IP packet is header-compressed, for example, an identifier indicating that the IP packet includes the reference clock information is added to the context identifier indicating the same IP data flow. The context identifier is stored in the compressed IP packet header. In this case, the receiving device 20 can extract the IP packet including the reference clock information by referring to the context identifier of the compressed IP packet header.

Also, an IP packet including reference clock information may be specified not to be header-compressed, or may be specified to be necessarily header-compressed. A predetermined context identifier may be assigned to the IP packet including the reference clock information, and it may be defined that all headers are compressed.

Also, an identifier indicating that the packet is an IP packet belonging to an IP data flow including reference clock information in the data type field of TLV, or an identifier indicating a compressed IP packet belonging to an IP data flow including reference clock information, etc. It is also possible to define The method will be described below.

The receiving device 20 determines the TLV data type, and if it is determined that the reference clock information is included, the receiving device 20 directly acquires the reference clock information included in the MMT packet from the IP packet.

In this way, the receiving device 20 extracts the reference clock information included in the MMT packet by extracting the bit string at the specific position from the IP packet or the compressed IP packet without analyzing the IP address, the port number, or the context identifier. May be. Extracting a bit string at a specific position means, for example, extracting information for a specific length from a position offset by a fixed-length byte from a TLV packet header, and thereby acquiring reference clock information.

The fixed length byte offset length for extracting the reference clock information is uniquely determined for each of the IP packet and the compressed IP packet. Therefore, after determining the TLV data type, the receiving apparatus 20 can acquire the reference clock information by immediately extracting information for a specific length from the position offset by a fixed-length byte.

The above method is merely an example, and the upper layer reference clock information may be acquired from the lower layer by defining other protocols and identifiers. For example, an identifier indicating whether or not the reference clock information is included in the IP packet may be stored in a field other than the TLV data type.

Further, for example, the reference time information included in the MMT packet may be extracted by extracting a bit string at a specific position from the IP packet or the compressed IP packet without analyzing the IP address, the port number, and the context identifier. FIG. 17 is a diagram showing a flow when a bit string at a specific position is extracted from an IP packet or a compressed IP packet. Note that the configuration of the receiving device 20 in this case is the same as the block diagram shown in FIG.

In the flow of FIG. 17, first, the decoding unit 11 decodes the transmission path encoded data received by the receiving unit 10 (S141), and extracts a TLV packet from the transmission path slot (S142).

Next, the TLV demultiplexer 12 analyzes the data type of the TLV packet and determines whether or not the data type is an IP including the reference clock information (S144). If it is determined that the data type is not an IP packet including reference clock information (No in S144), the flow ends. When it is determined that the data type is an IP packet including the reference clock information (Yes in S144), the IP packet and the MMT packet are analyzed to determine whether the IP header is compressed (S145).

When the IP header is not compressed (No in S145), reference clock information included in the MMT packet at a position offset by a fixed length N bytes from the TLV header is acquired (S146). If the IP header is compressed (Yes in S145), reference clock information included in the MMT packet at a position offset by a fixed length M bytes from the TLV header is acquired (S147).

Finally, the reference clock generation unit 16 generates a system clock based on the reference clock information (S148).

In addition, since the data structure of the IP packet header differs depending on whether the IP packet is IPv4 or IPv6, the fixed length N bytes and M bytes have different values.

Normal MMT packets including audio, video, and control signals are subjected to DEMUX processing in normal steps, whereas MMT packets including reference clock information are collectively processed by DEMUX processing from a lower layer to an upper layer. Done. Thereby, even if the reference clock information is stored in the upper layer, the reference clock information can be acquired in the lower layer. That is, the processing for acquiring the reference clock information can be reduced, the time until acquisition of the reference clock information can be shortened, and the hardware can be easily implemented.

(Other embodiments)
Although the first embodiment has been described above, the present disclosure is not limited to the above-described embodiment.

In the above embodiment, the method for storing the reference clock information has been described. However, a plurality of reference clock information may be transmitted in one or more layers. When a plurality of reference clock information is transmitted, the receiving device 20 may select either one of the reference clock information and use it to generate a reference clock (system clock), or use both to generate the reference clock. It may be generated. At this time, the receiving device 20 may select highly accurate reference clock information, or may select reference clock information that can be acquired earlier.

Also, for example, it is assumed that more accurate reference clock information is transmitted in addition to the 32-bit short format NTP included in the conventional MMT packet header. In such a case, information for reproducing the 32-bit short format NTP by the receiving apparatus 20 using the highly accurate reference clock information is further transmitted from the transmitting side. Such information is, for example, time information indicating a relative relationship between clocks, and a configuration in which the information is transmitted using CRI_descriptor () or the like is conceivable.

Note that when the reception device 20 can reproduce the 32-bit short format NTP, the NTP field included in the conventional MMT packet header is unnecessary. For this reason, other information may be stored in the NTP field, or header compression may be performed by reducing the NTP field. When header compression is performed, information indicating that the NTP field has been reduced is transmitted. When the NTP field is reduced, the receiving apparatus 20 generates a reference clock using other reference clock information and reproduces a 32-bit short format NTP.

In addition, when the MMT packet is transmitted using the communication transmission path, the communication receiving apparatus may use the 32-bit short format NTP for QoS control and may not use the reference clock information. Therefore, the reference clock information may not be transmitted on the communication transmission path. If the end-to-end delay of the communication transmission path is within a certain range, the reference clock information may be used for clock recovery.

In the first embodiment, the case where the MMT / IP / TLV method is used has been described as an example. However, a method other than the MMT method may be used as the multiplexing method. For example, the present disclosure can be applied to the MPEG2-TS system, the RTP system, or the MPEG-DASH system.

As header compression methods for IP packets, there are RoHC (Robust Header Compression) and HCfB (Header Compression for Broadcasting).

As a method for storing IP packets in broadcast, there are a GSE (Generic Stream Encapsulation) method and an IPoverTS method using ULE (Uniform Light-weight. Encapsulation) in addition to the TLV method.

The present disclosure can be applied to any of the above-described methods. By applying the present disclosure, the time until acquisition of the reference clock information in the receiving device 20 is reduced, the processing is reduced, and the hardware is implemented. High accuracy of the clock can be realized.

Also, the present disclosure may be realized as a transmission device (transmission method) that transmits a transmission slot that stores reference clock information by the method described above. Hereinafter, the configuration of such a transmission apparatus will be supplemented. FIG. 18 is a block diagram illustrating a functional configuration of the transmission apparatus. FIG. 19 is a diagram illustrating an operation flow of the transmission apparatus.

As shown in FIG. 18, the transmission device 30 includes a generation unit 31 and a transmission unit 32. Note that the components of the transmission device 30 are specifically realized by a microcomputer, a processor, a dedicated circuit, or the like.

The transmission device 30 is specifically a broadcast server, and is an example of the “transmission side” in the first embodiment.

The generation unit 31 generates, for example, a transmission slot that stores a plurality of slots in which one or more TLV packets in which IP packets are stored are stored (S151 in FIG. 19). Further, the generation unit 31 includes reference clock information such as NTP used for reproduction of content (for example, broadcast content such as video or audio) in the reception device 20 in the TLV packet positioned at the head in the transmission slot. . Specifically, the generation unit 31 includes an encoding unit that encodes broadcast content, an MMT multiplexer, an IP multiplexer, a TLV multiplexer, and the like. The TLV packet is an example of a first transmission unit, the slot is an example of a second transmission unit, and the transmission slot is an example of a transmission frame.

The transmission unit 32 transmits the transmission slot (transmission path encoded data including the transmission slot) generated by the generation unit 31 through broadcasting (S152 in FIG. 19).

As described in the first embodiment, according to such a transmission device 30, the reception device 20 acquires the reference clock information by including the reference clock information in the TLV packet located at the head in the transmission slot. Processing can be simplified. Therefore, it is possible to shorten the time until the receiving device 20 acquires the reference clock information.

In the above embodiment, each component may be configured by dedicated hardware or may be realized by executing a software program suitable for each component. Each component may be realized by a program execution unit such as a CPU or a processor reading and executing a software program recorded on a recording medium such as a hard disk or a semiconductor memory.

Each component may be a circuit. These circuits may constitute one circuit as a whole, or may be separate circuits. Each of these circuits may be a general-purpose circuit or a dedicated circuit.

For example, in each of the above embodiments, another processing unit may execute a process executed by a specific processing unit. Further, the order of the plurality of processes may be changed, and the plurality of processes may be executed in parallel.

As described above, the reception device (reception method) and the transmission device (transmission method) according to one or more aspects have been described based on the embodiment, but the present disclosure is not limited to this embodiment. . Unless it deviates from the gist of the present disclosure, various modifications conceived by those skilled in the art have been made in this embodiment, and forms constructed by combining components in different embodiments are also within the scope of one or more aspects. May be included.

The transmission method of the present disclosure is useful as a transmission method that can reduce processing for acquiring reference clock information on the receiving side when the MMT method is applied to a broadcasting system.

DESCRIPTION OF SYMBOLS 10 Reception part 11 Decoding part 12 TLV demultiplexer 13 IP demultiplexer 14 MMT demultiplexer 15 Reference clock information extraction part 16 Reference clock generation part 17 Synchronization part 18 Decoding presentation part 20 Reception apparatus 30 Transmission apparatus 31 Generation part 32 Transmission part

Claims (9)

1. A transmission method in content transmission using an IP (Internet Protocol) packet performed through broadcasting,
   Generating a transmission frame that stores a plurality of second transmission units in which one or more first transmission units in which the IP packets are stored are stored;
   Transmitting the generated frame, and
   In the generation step, reference clock information indicating a time for reproducing the content is included in the first transmission unit located at the head in the second transmission unit at the head in the frame. .
2. The first transmission unit is a variable length transmission unit;
   The transmission method according to claim 1, wherein the second transmission unit is a fixed-length transmission unit.
3. The transmission method according to claim 1 or 2, wherein the IP packet stored in the first transmission unit located at the head is an IP packet not subjected to header compression.
4. The first transmission unit is a TLV (Type Length Value) packet,
   The second transmission unit is a slot in the advanced BS transmission system,
   The transmission method according to any one of claims 1 to 3, wherein the frame is a transmission slot in an advanced BS transmission system.
5. The transmission method according to any one of claims 1 to 4, wherein the reference clock information is NTP (Network Time Protocol).
6. The transmission method according to any one of claims 1 to 5, wherein, in the transmission step, the frame is transmitted at a predetermined transmission cycle.
7. A receiving method in content transmission using IP packets performed through broadcasting,
   A transmission frame storing a plurality of second transmission units including one or more first transmission units in which the IP packet is stored, the first transmission unit in the frame being positioned at the head A receiving step of receiving a frame including reference clock information in the first transmission unit;
   Extracting the reference clock information from the received frame;
   A generating step of generating a clock for reproducing the content using the extracted reference clock information.
8. A transmission device used for content transmission using IP packets performed through broadcasting,
   A generating unit that generates a transmission frame storing a plurality of second transmission units in which one or more first transmission units in which the IP packet is stored are stored;
   A transmission unit for transmitting the generated frame,
   The generation unit includes reference clock information indicating a time for reproducing the content on a reception side in a first transmission unit positioned at a head in a second transmission unit at a head in the frame.
9. A receiving device used for content transmission using IP packets performed through broadcasting,
   A transmission frame storing a plurality of second transmission units including one or more first transmission units in which the IP packet is stored, the first transmission unit in the frame being positioned at the head A receiving unit that receives a frame in which the reference clock information is included in the first transmission unit that
   An extraction unit for extracting the reference clock information from the received frame;
   And a generation unit that generates a clock for reproducing the content using the extracted reference clock information.

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