JP7166996B2 - receiver - Google Patents

Description

The present invention relates to a receiving device capable of receiving broadcast programs, in which received contents are transmitted to other devices (client devices: display devices, terminals, televisions, etc.) via a network and displayed.

Multimedia services in advanced BS digital broadcasting and advanced broadband CS digital broadcasting are collective names for closed captioning services, superimposed text services, and data content services, and are performed according to the operating rules of Non-Patent Document 1.

Advanced Broadband Digital Satellite Broadcasting Operational Regulations ARIB TR-B39 Version 2.1 (Volume 5) April 12, 2019 Revised 2.1, Association of Radio Industries and Businesses

Digital multiplexing method (TLV method) data is classified into multiple IP data flows (SI dedicated data flow, at least one or more same IP data flow corresponding to service, etc.) data is classified into categories, and these multiple categories In order to be able to display the multiplexed data on a client terminal (display device, TV, etc.) external to the receiving device, it is necessary to configure packet data when transmitting data from the receiving device to the network.

A receiving unit for receiving digital multiplexed data, a control unit for recognizing an IP data flow related to multiplexing of IP packets, an IP data flow corresponding to a service, and a shared service IP data flow associated with the IP data flow corresponding to the service. The package list table (PLT) of the IP data flow in the data recognized by the control unit, video signal data (video MPU), audio signal data (audio MPU) and video of the IP data flow corresponding to the service Table information (MPT) necessary to acquire , audio, and subtitles, and service-shared IP data (character super MPU) of the service-shared IP data flow associated with the service-supported IP data flow are multiplexed and transmitted over the network. A receiver, comprising: a transmitter that

Data in which a plurality of categories are multiplexed by a digital multiplexing method (TLV method, etc.) (data of service-shared IP data flow, etc.) can be displayed on a client terminal (display device, TV, etc.) external to the receiving device.

The figure which shows the structure of a receiver. FIG. 4 is a diagram showing a data editing operation performed by a control unit; FIG. 4 is a diagram showing an example of location designation in a digital multiplexed service shared asset.

In advanced BS/CS, a method of outputting TLV/MMT to the IP interface and sending it from the server device to the client device is currently under consideration.

On the other hand, when a device that has recorded an advanced BS/CS program sends the recorded data as a server, there is a possibility that the video and audio that should be played back on the client device side may not be obtained depending on the configuration of the recorded data.

When processing the recorded data on the server side (receiver) and sending it to the client via the IP interface, it is necessary for the client to be able to reproduce the desired video and audio correctly.

The program data stored in the HDD is data received by radio waves of broadcasting. However, among the received data, data that is not related to display on a display device directly connected to the receiver (data related to conditional access such as ECM and EMM, application data, etc.) is deleted, and It is common not to save to .

Various measures can be taken so that even if there is no such deleted data in the recorded receiver itself, the recorded data can be played back correctly when displayed on a display device directly connected to the receiver.

However, it is necessary to exchange data between devices on the home network using a predetermined protocol, and such data (data unrelated to display on a display device directly connected to the receiver) cannot be exchanged. is time consuming.

Therefore, there are methods and means for leaving data other than data sent directly to the display device (TV) without going through the home network (part of the data deleted during normal recording) along with the video and audio, and the home network and other than the home network. There is a need for methods and means for transmitting data over multiple networks.

FIG. 1 shows the configuration of the receiver 1 and devices connected to the receiver 1 . The receiving device 1 can be read as a digital media server (DMS). The receiver 1 comprises a receiver 2 , a controller 3 , a transmitter 4 , a storage 5 and a multimedia interface 6 . Devices connected to the receiving device 1 include a client device 7 and a media device 8 .

Receiver 2 includes an advanced BS tuner and/or an advanced CS tuner. The receiver 2 can receive digital multiplexed (TLV) broadcast signals (transponder in FIG. 2) such as advanced BS and/or advanced CS broadcasts.

The control unit 3 identifies the media processing units of various messages, images, and sounds associated with the IP data flow and the like from the data of the received broadcast signal, and performs control to store the data in the storage unit 5 . The control unit 3 performs control to combine various messages and media processing unit data so that content corresponding to the client device 7 and the media device 8 can be displayed. The control unit 3 may perform control to combine the data via the storage unit 5, or may edit and control the data stream in real time.

The transmission unit 4 is an IP interface that transmits data combined with various messages and media processing unit data in the control unit 3 to the client device 7 via the network. This network includes public networks, LANs, WANs, and so on.

A multimedia interface 6 is an interface for connecting a media device 8 such as a TV and the receiving device 1 .

The client device 7 can be read as a digital media platform. The client device 7 is a device for displaying contents including various messages transmitted from the transmission section 4 via the network and data of the media processing unit.
The storage unit 5 may be inside the receiving device 1 or may be externally provided outside the receiving device 1 . Moreover, when the memory|storage part 5 is outside, the case where it connects via a network is also included.

The receiving device 1 includes a receiving unit 2 for receiving digital multiplexed data, an IP data flow related to multiplexing of IP packets, an IP data flow corresponding to a service, and a service-shared IP data flow associated with the IP data flow corresponding to the service. In the data recognized by the control unit 3, the package list table (PLT) of the IP data flow, and the video signal data (video MPU) and audio signal data (video MPU) of the IP data flow corresponding to the service audio MPU), table information (MPT) necessary to acquire video, audio, and subtitles, and service-shared IP data (character super MPU) of the service-shared IP data flow associated with the service-supported IP data flow. It has a transmission unit 4 that multiplexes and transmits over the network.

The operation of FIG. 1 will be specifically described below.
Advanced BSs operate to transmit one service as one IP data flow. In this case, when a single program is selected and recorded and stored, the flow is as follows.

(1) Find the packet ID of the PA message that stores the MPT by referring to MMT_general_location_info described in the PLT.
(2) Find packet IDs of video and audio assets by referring to MMT_general_location_info described in MPT.
(3) Identify video assets and audio assets to be played.

By the way, in advanced CS, Advanced Broadband Satellite Digital Broadcasting Operational Regulations ARIB TR-B39 Version 2.1 (Volume 5) April 12, 2019 2.1 revision, Association of Radio Industries and Businesses, Chapter 4, Chapter 13, 13.1 IP data flow and message transmission, and Fig. 13-2 shows an example of location designation in assets shared by services. A system is in operation in which a guide service for viewing procedures for contracted programs is transmitted.

In this way, when outputting or recording a shared IP data flow together with an IP data flow containing video/audio assets, the control unit 3 multiplexes a plurality of IP data flows corresponding to the service into a single Output or accumulate as recorded data.

On the other hand, when reproducing recorded data that has been unified by multiplexing multiple IP data flows, it is not enough to find the packet ID of the PA message that stores the MPT by referring to MMT_general_location_info after obtaining the PLT. of MPT cannot be identified.

Because the packet ID is unique for each IP data flow, different data may be stored in data multiplexed with multiple IP data flows, even if the packet ID is the same. be .
In this case, when obtaining the MPT of each IP data flow (corresponding to each service of the same IP data flow), each IP data flow also needs to be identified.

The flow for identifying the IP data flow in the control unit 3 is as follows.
(1) Discover PLT.
(2) discover the source and destination IP addresses of the desired IP data flow;
(3) Find the partial IPv6 header (IPv6_header_wo_length) of the received header-compressed IP packet.
(4) Identify the pair of CID (Context ID) and source/destination IP address.

For the partial IPv6 header (IPv6_header_wo_length), see ARIB TR-B39 (Volume 4), Part 1 Advanced Wideband Satellite Digital Broadcasting Operational Rules, Volume 7, Chapter 5, 5.5.3.3 Header Compression IP Packet Structure and Operational Rules, Table 5-26 Header compression IP packet structure and Table 5-27 Partial IPv6 header (IPv6_header_wo_length) structure are stipulated.

The partial IPv6 header (IPv6_header_wo_length) is specified in 5.5.3.3 Header-compressed IP packet structure and operation rules, "If an IP data flow contains an IP packet that undergoes header compression, the header-compressed IP packet with a context identification header type of 0x60 is It must be sent at least once every 500msec for each data flow, but at the time of hierarchical modulation, it should be sent at least once every 500msec for header-compressed IP packets sent in the slots assigned to the lower layers. ”, and it is a rule that it is sent at a frequency of about once every 500 msec.

In addition, not all tables are recorded when recording by the control unit 3, and depending on the specifications of the receiving device, it is conceivable that unused tables such as EMMs and ECMs are not stored. In other words, EMMs and ECMs are messages that are used to make the conditional access system work, so it is not desirable to retransmit them to the client device.
In addition to this, an operation that does not retransmit multimedia service data (MH-AIT, DDMT, DAMT), logo data (MH-SDTT), etc. to the client device is also conceivable.

In such a case, the client device side 7 that requests the reproduction of data recognized by the control unit 3 or recorded may have a CID (Context ID) that identifies each IP data flow and the source.
This is because there is no partial IPv6 header that identifies the CID/IP address pair.

Recognition and recording of the control unit 3 data are performed according to the following procedure.
(1) Find the PLT in the TVL stream.
(2) identify the source IP address of the IP data flow of the service to be recorded;
(3) monitor header-compressed IP packets for each IP data flow;
(4) Find the partial IPv6 header and identify the CID and source IP address pair.
(5) Identify the target service by the CID described in the compressed IP packet.
(6) Accumulate necessary control information (eg: PLT and MPT) and assets (eg: video, audio, caption MPU) corresponding to the specified target service.
(7) The partial IPv6 header (IPv6_header_wo_length) is stored once every 500msec, so the partial IPv6 header is stored in the header-compressed packet containing the PLT and MPT so that the necessary control information is accumulated together with the video/audio. to accumulate.
The client device 7 that reproduces the content data created in this manner can smoothly identify the pair of the CID and the source IP address and reproduce the video and audio.

Alternatively, in addition to PLT and MPT in the control unit 3, some of CAT, MH-SDTT, MH-TOT, MH-CDT, MH-EIT, MH-SDT, MH-BIT, DDMT, DAMT, MH-AIT, and EMT Or copy it into a header-compressed IP packet that stores the whole thing. That is, it is copied to the stored header-compressed IP packets other than ECM and EMM.

Alternatively, the controller 3 accumulates packets containing only the partial IPv6 header (IPv6_header_wo_length). Partial IPv6 headers are sent from the source once every 500msec and include those containing EMM and/or ECM.

Alternatively, in the response header to be returned in response to the HTTP GET request sent by the client device 7 at the start of playback, the SI-dedicated IP data flow, the IP data flow including the MPT, the video asset, and the audio asset, and the shared IP data flow , the information corresponding to the partial IPv6 header (IPv6_header_wo_length), or the CID, or both of them are stored or combined, and transmitted via the transmission unit 4.

Alternatively, in order for the client device 7 to acquire the information of the content, the control unit 3 may include the SI-dedicated IP data flow, MPT, video assets, and Information equivalent to the partial IPv6 header (IPv6_header_wo_length), CID, or both of the IP data flow including voice assets and the shared IP data flow are stored or combined and transmitted via the transmission unit 4 .

In all the above methods, when the control unit 3 sends the partial IPv6 header (IPv6_header_wo_length), the control unit 3 also stores or combines the information of the partial UDP header (UDP_header_wo_length) and transmits it via the transmission unit 4 .

FIG. 2 shows the data editing operation performed by the control section 3. As shown in FIG.
The data 10 (TLV stream) received from the broadcast received by the receiver 2 includes an SI dedicated IP data flow 20 and an IP data flow 30 for service transmission. The SI dedicated IP data flow 20 is composed of compressed IP packets 21 , compressed IP packets 22 and compressed IP packets 23 . An IP data flow 30 for service transmission consists of compressed IP packets 31 , 32 and 33 . Compressed IP packet 21 includes full header 211 . Compressed IP packet 32 includes full header 311 .

The control unit 3 recognizes each compressed IP packet of the data 10 that the receiving unit 2 receives from the broadcast. By editing the data 10 received by broadcasting, the control unit 3 can compose data 40 to be recorded and stored or transmitted to the client device 7 . Specifically, compressed IP packets 21 and 32 are recognized. Since this compressed IP packet is not required for content display on the media device 8, it is not necessary to record and store it. On the other hand, the client device 7 needs the full headers 211 and 321 included in the compressed IP packets 21 and 32 . Therefore, the control unit 3 extracts the full header 211 and adds the full header 211 to the compressed IP packet 23 to configure the compressed IP packet 23'. Furthermore, the control unit 3 extracts the full header 321 and adds the full header 321 to the compressed IP packet 33 to configure the compressed IP packet 33'.

The data 40 edited and configured by the control unit 3 to be recorded and stored or transmitted to the client device 7 is composed of an SI dedicated data flow 20' and an IP data flow 30' for service transmission.

The SI dedicated data flow 20' consists of compressed IP packets 22' and compressed IP packets 23'. The compressed IP packet 22' of the SI dedicated data flow 20' is the same as the compressed IP packet 22'. Compressed IP packet 23' of SI dedicated data flow 20' is obtained by editing compressed IP packet 23 and adding full header 211. FIG.

The IP data flow 30' for service transmission consists of compressed IP packets 31' and compressed IP packets 33'. The compressed IP packet 31 ′ of the IP data flow 30 ′ for service transmission is the same as the compressed IP packet 31 . The compressed IP packet 33' of the IP data flow 30' for service transmission is the compressed IP packet 33 with a full header 321 added.

As an illustration of the above description, Figure 3 illustrates the location of service-sharing assets for IP data flow and message transmission.

A transponder consists of a TLV stream (TLV_Stream). TLV_Stream consists of AMT, TLV-NIT and UDP/IP packets.

AMT provides a list of multicast groups of IP packets that constitute each service transmitted in the broadcast network. The TLV-NIT carries information relating to the physical organization of the multiplex/TLV stream carried by the broadcast network and information relating to the broadcast program. and characterize the network itself. UDP/IP stands for User Datagram Protocol/Internet Protocol, a communication protocol that runs over IP. Since IP packets are transmitted as they are, high-speed transmission is performed without processing such as error correction detection and ARQ.

UDP/IP includes NTP dedicated IP data flows including network time control (NTP), SI dedicated IP data flows including service information (SI), identical IP data flows corresponding to at least one service and shared service IP data flows. is sent in UPD/IP format. It is included.

The SI dedicated IP data flow contains M2 section messages, CA messages and PA messages.

The M2 section message is used to transmit the section extension format of MPEG-2 Systems, and includes EMM, MH-SDTT, MH-CDT, MH-EIT, MH-SDT and MH-BIT. EMM is the transmission of personalized information including contract information for each subscriber and a work key for decrypting common information.

The CA message is a packet identifier (PID) of individual information among pay TV related information and includes CAT. CAT is one of the transmission control signals in the multiplex system, and means a table used for transmission of information related to conditional access.

The PA message contains the Package List Table PLT. A package list table (PLT) is table information for indirectly specifying an MPT table, which is information that indirectly specifies packet IDs for video, audio, and subtitles. That is, PLT lists IP data flows and packet IDs that carry PA messages of MPEG Media Transport (MMT) packages provided as broadcast services.

The same IP data flow is formed for each service unit such as video and audio, and includes video MPU, audio MPU, caption MPU, application MPU, data transmission message, M2 section message and PA message.

MPU is an abbreviation for Media Processing Unit, which is the unit for video and audio processing. An MPU is a unit that includes one or more access units and can perform composite processing of video and audio by itself. MPU belongs to the same asset layer. By using a sequence number for each MPU, the MPU can be distinguished from other MPUs.

The data transmission message includes a data directory management table DDMT and a data asset management table DAMT.

The M2 section message is sent to the MH application management table MH-AIT, the event message table EMT that provides a means for sending a message from the sender to the application of the receiver, and common information, such as date and time information and a scramble key, to the receiver. Contains entertainment control messages ECM.

The PA message contains an MMT package table MPT that gives information that makes up the package, such as the list of assets and their locations. The MPT package table is table information that indirectly specifies packet IDs for video, audio, and subtitles.

The service-shared IP data flow includes MPU assets common to the service flow, such as closed caption super MPU.

Data in which a plurality of categories are multiplexed by a digital multiplexing method (TLV method, etc.) (data of service-shared IP data flow, etc.) can be displayed on a client terminal (display device, TV, etc.) external to the receiving device.

While several embodiments of the invention have been described, these embodiments have been presented by way of example and are not intended to limit the scope of the invention. The above-described embodiments can also be regarded as a receiving device, a receiving method, a transmitting device, a transmitting method, and a transmitting/receiving system.
These novel embodiments can be implemented in various other forms, and various omissions, replacements, and modifications can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and equivalents thereof. Furthermore, in each constituent element of the claims, even if the constituent element is divided and expressed, a plurality of constituent elements are expressed together, or a combination of these is expressed, it is within the scope of the present invention. Moreover, a plurality of embodiments may be combined, and examples configured by such combinations are also within the scope of the invention. In addition, when the claims are expressed as control logic, when expressed as a program including instructions for executing a computer, and when expressed as a computer-readable recording medium in which the instructions are written, the apparatus of the present invention is applied. be. Also, the names and terms used are not limited, and other expressions are included in the present invention as long as they have substantially the same content and the same meaning.

1: receiving device, 2: receiving unit, 3: control unit, 4: transmitting unit, 5: storage unit, 6: multimedia interface, 7: client device, 8: media device.

Claims (1)

a receiver for receiving digital multiplexed data;
a control unit recognizing an IP data flow associated with multiplexing of IP packets, an IP data flow corresponding to a service, and a service shared IP data flow associated with the IP data flow corresponding to the service;
Among the data recognized by the controller:
a package list table for the IP data flow;
Table information necessary for acquiring video signal data, audio signal data, video, audio, and subtitles of the IP data flow corresponding to the service;
a transmitting unit that multiplexes and transmits over a network shared service IP data of a service shared IP data flow associated with the service corresponding IP data flow;
A receiving device characterized by comprising:

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