KR20190073321A - Method configuring and transmitting m-unit - Google Patents

Abstract

According to the present specification, a method for setting and transmitting an M-unit in a system is disclosed. The method for setting an M-unit in a system comprises the steps of: receiving a media fragment unit (MFU) from a media encoder; and configuring an M-unit including the MFU in a payload, wherein the M-unit includes an M-unit header including information required to be discriminated in every M-unit and a reference header including information independent of the M-unit.

Description

[0001] METHOD CONFIGURING AND TRANSMITTING M-UNIT [0002]

The present invention relates to an M unit of an MMT (MPEG Media Transport), and more particularly to a method and apparatus for setting up or transmitting an M unit.

In recent years, ISO / IEC JTC1 / SC29 / WG11 (hereinafter referred to as MPEG) has been standardizing MPEG-H, a multimedia coding expression and multiplexing transmission standard to be used in UHDTV (Ultra High-Definition TV) MPEG-H is expected to be published as a set of standards consisting of part 1 system, part 2 video, part 3 audio, etc., similar to existing MPEG-1, MPEG-2 and MPEG-4 systems. Part 1 of the MPEG-H is the MPEG Media Transport (MMT), Part 2 is the High-Efficiency Video Coding (HEVC), Part 3 is not yet finalized, but UHDTV The next generation of audio compression coding standards to standardize. MMT is a next-generation multimedia multiplexing transmission standard that is being standardized in MPEG, following MPEG-2 TS (Transport Stream) standard. HEVC is the next generation video compression coding standard considering application to UHDTV which is jointly standardized by ISO and ITU-T.

MMT is IP-friendly and aims to deliver multimedia using several different types of channels. MMT consists of three functions: Encapsulation (E), Delivery (D), and Control (C). In the E function, the multimedia contents are packed into one object. In the D function, the packaged contents are packetized according to the IP protocol and transmitted, and the C function carries various control information including the multimedia service search information.

Currently, many companies and schools participate in MMT standardization in Korea, and the technology is being proposed in every detail of MMT. In particular, a method of transmitting and receiving an M-UNIT of a new structure is required in the MMT.

SUMMARY OF THE INVENTION The present invention provides a method and apparatus for setting an M unit of a new structure.

It is another object of the present invention to provide a method and apparatus for transmitting an M unit of a new structure.

According to one aspect of the present invention, a method for setting up an M-unit in a system includes receiving a Media Fragment Unit (MFU) from a media encoder; And configuring an M-unit comprising the MFU in a payload, the M-unit comprising: an M-unit header including information that needs to be separated for each M-unit; and an M- Lt; RTI ID = 0.0 > a < / RTI > reference header.

According to another aspect of the present invention, a method for transmitting an M-unit in a system includes receiving a Media Fragment Unit (MFU) from a media encoder; And configuring the payload to include an M-unit header including information that needs to be separated for each M-unit by an M-unit including the MFU and a reference header including information that is non-dependent on the M-unit ; And transmitting the M-units.

According to the present invention, an M-unit including a reference header can perform archiving and transport through header division. In addition, an M-unit including a reference header does not need to attach repeated fields to each unit. If an M-unit is delivered prior to the unit, it can be sent to an arbitrary position, and a retransmission policy for a packet error Can be taken independently, and in-band transmission as well as in-band transmission is possible.

1 shows an example of a structure of a reference header according to the present invention.
2 shows an example of a plurality of MFU aggregation methods according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Also, in order to clearly illustrate the present invention in the drawings, portions not related to the present invention are omitted, and the same or similar reference numerals denote the same or similar components.

An M-unit is a basic unit for a system (eg, a multimedia system) to pass through a MFU (Media Fragment Unit) and then proceed to the next process.

The MFU is the output of a media encoder (e.g., a video encoder or an audio encoder). At this time, the header of the MFU is generated by the media encoder and transmitted to the system. The header of the MFU is used as a path for transmitting information to the system that is useful for system operation (for example, transmission or storage of information or signals) among information that the media encoder has or knows. The MFU is the output of a media encoder, which consists of encoded data (eg, audio data or video data) and an MFU header.

The basic operation related to the M-unit is as follows: 1) an operation of distinguishing a plurality of MFUs when an M-unit includes a plurality of MFUs, 2) an operation of distinguishing AUs (Access Units) When the M-unit is a Timed M-Unit, it transmits or distinguishes time information such as CTS (Composition Time Stamp) / DTS (Decode Time Stamp) at the level of an Encapsulation layer for each AU . Here, CTS means a time when the corresponding MFU is displayed on the screen, and DTS means a time when the corresponding MFU is consumed in the decoder.

Hereinafter, the structure of the M-unit according to the present invention will be described. Specifically, 1) structure and use of a reference header, 2) aggregation of a plurality of MFUs, 3) classification of AUs, and 4) time stamp information. A system (eg, a multimedia system) can configure (or configure) an M-unit with the following structure. In addition, the system can transmit the set M-unit to another system or another device.

1 shows an example of a structure of a reference header according to the present invention.

Referring to FIG. 1, the header of the M-unit according to the present invention may be a two-staged header structure including a reference header (RH). For example, it may be a two-stage structure of a reference header and an M-unit header.

Leaving only the essential information that is repeated per payload in the front part of the payload (this part is referred to as the first stage header), and the remaining information can be separated into a separate header, referred to as the reference header (This portion is referred to as a second stage header).

At this time, the reference header may exist as a unit separate from the payload unit. It is also possible to send the reference header at an arbitrary point in time, if it is earlier in time than the M-unit to be used (it does not necessarily have to be located immediately before the M-unit). In addition, the reference header can freely select either in-band transmission or out-of-band transmission.

In addition, the reference header may contain information that is required at the M-unit level but does not need to be distinguished for each M-unit or may contain information that does not need to be dependent on a particular M-unit, while the prefix MUH Prefix MU-Header) can contain information that needs to be separated for each M-unit, unlike the reference. It is optional for the M-unit to include a reference header, and it is not necessary to include the reference header.

For example, the M-unit may have a structure in which a reference header (RH) and an M-unit header (MHU) are serially arranged. This can be referred to as a serial position (110).

As another example, the M-unit may be a structure in which RH and MHU are both located in front of the payload. This is called the aggregated position (120).

As another example, the M-unit may be a structure that performs out-of-band transmission with RH. This can be referred to as OOB fetch (Out-of-Band Fetch) 130. The MUH performs an OOB request to RH, and the RH performs an OOB fetch to MUH.

As another example, an M-unit may be a structure 140 that includes RH, one for each M-unit (or payload of an M-unit). That is, RH and MUH can be one-to-one correspondence.

As another example, the M-unit may be a structure 150 that does not include RH.

The M-unit including the reference header described above can perform archiving and transport through header division. In general, in the case of a file archiving application, it is preferable to arrange the header information in one place. In the case of a transmission application, positioning header information between required packet lines (interleaved position.

In addition, an M-unit including a reference header may not have a field repeated every several times. If it is delivered before that unit, it can be sent to any position.

In addition, an M-unit including a reference header can independently take a retransmission policy for a packet error.

In addition, an M-unit containing a reference header is capable of out-of-band transmission as well as in-band transmission.

On the other hand, a method of expanding to accommodate various information in the header according to the bit option such as M2TS can not adopt a separate retransmission policy for the header, There is also no flexibility. Also, the header can not be transmitted out-of-bound (OOB).

2 shows an example of a plurality of MFU aggregation methods according to the present invention.

Referring to FIG. 2, an M-unit is a structure that can accommodate two or more MFUs in one MU.

The system can choose whether to aggregate more than one MFU in a payload M-unit. The specific description for the aggregation of the MFUs is contained within the RH, not the MHU. Because the size of the technology for multiple MFUs is large for direct inclusion in the MUH, and for media with a simple structure (eg audio codec), there are many cases where the structure of the MU is the same (or equal to the size of the MFUs in the MU) , Because not every M-unit needs to have a dedicated description.

Meanwhile, according to the present invention, the MFUs included in the MU can be divided into AU units. Here, AU (eg, MPEG AU) is the smallest data entity to which timing information is delivered (attribute to) and is the smallest unit sharing the same time information. Therefore, in a media related system AU identification is very important.

Also, the MU may include an AU start / end indicator, which may indicate an AU at which the MFU starts, an AU at which the MFU terminates, an AU number or an AU And may indicate the number.

Meanwhile, according to the present invention, the M-unit may further include timestamp information.

The system can provide CTS and DTS information to MFUs included in the M-unit to provide time information of their screen configurations. At this time, the CTS and DTS information provide a Constant Mode, and the DTS field may be selectively used. Also, the CTS and DTS values can be described in MFU units. If a constant mode is used, an additional description may be included in the reference header. For example, the starting point or incremental gaps of the CTS may be included in the reference header.

Hereinafter, the syntax and semantics of the M-unit according to the present invention will be described.

As described above, the header of the M-unit includes a reference header (RH) or a payload type (MHU).

The following table shows an example of the syntax and semantics of the M-unit according to the present invention.

The following constituent elements are not limited to the order, and all constituent elements are not necessarily included, but may be constituted by some constituent elements.

 Here, MU_type designates a reference header use mode of the M-unit, and may be composed of two bits, for example. The following table shows an example of the bit configuration of MU_type. The following constituent elements are not limited to the order, and all constituent elements are not necessarily included, but may be constituted by some constituent elements.

The following table shows an example of the syntax and semantics of the M-unit base header. An M-unit base header is a header that is not a reference header among M-unit headers. At this time, the M-unit base header may be located at the beginning of the payload type M-unit. The following constituent elements are not limited to the order, and all constituent elements are not necessarily included, but may be constituted by some constituent elements.

Here, flag_multiple_MFU indicates that the M-unit includes two or more MFUs if it has a value of "1", and indicates that the M-unit has only one MFU if it has a value of "0". Preferably, the aggregation of the MFUs can be used in a lossless environment (eg lossless transmission channels such as TCP or local file manipulation).

Also, the flag_random_access_point indicates that the MU includes an MFU that starts with a random access point of the media among the MFUs included in the M-unit if the flag has a value of "1 ".

Also, flag_timed indicates that the M-unit includes timed media data if it has a value of "1 ". Here, timed media refers to media data (e.g., audio frames, video frames) to which a time to be consumed is designated as a specific time. If flag_timed has a value of "0 ", it indicates that the M-unit includes non-timed media data. Here, non-timed media data means media data whose time to be consumed is not specified.

Also, if the flag_constant_CTS has a value of "1 ", it indicates that the AU belonging to the M-unit operates in a " constant mode ". Here, the constant mode is a mode in which a time interval between AUs of all M-units belonging to a corresponding mode is constant, and a start value and a time interval are indicated in a reference header. If flag_constant_CTS has a value of "0 ", it indicates that the AU belonging to the M-unit operates in a " Full Descriptive Mode ". Here, the full discrete mode is a mode for explicitly writing a dedicated CTS value for all AUs of all M-units belonging to the corresponding mode.

If flag_DTS_by_CTS has a value of "1 ", it indicates that the DTS value of the AU of the M-unit is the same as the CTS value of the same AU. The corresponding M-unit does not have a header field corresponding to the DTS. If flag_DTS_by_CTS has a value of "0 ", it indicates that all AUs of the M-unit have a dedicated DTS value.

For pl_seqno, if the reference header mode (ref_header_mode) has a value of "01" or "10", the M-unit uses the reference header and the corresponding M- A sequence number is assigned to specify a group of units). pl_seqno has a value that increases by 1 for each M-unit for the M-unit stream. pl_seqno is incremented only for the payload type M-unit, and reference headers that may exist in the middle are not counted.

The following table shows an example of the syntax and semantics of an M-unit of payload type. The following constituent elements are not limited to the order, and all constituent elements are not necessarily included, but may be constituted by some constituent elements.

Here, the CTS (Composition Time Stamp) indicates a time when the corresponding MFU is displayed on the screen. DTS (Decode Time Stamp) means the time that the corresponding MFU is consumed in the decoder.

The reference header of the M-unit may include one or more sections, and each section may have a unique section ID (section ID).

The system can adjust the number of reference headers of the M-unit as needed, and the type of section included in each reference header can be arbitrarily selected.

Table 5 shows an example of a reference header of an M-unit. The following constituent elements are not limited to the order, and all constituent elements are not necessarily included, but may be constituted by some constituent elements.

Here, with respect to the section ID (section ID), the reference header of the M-unit can be divided into several sections according to the information to be provided, the section ID is an ID for distinguishing between sections, It can have an unsigned integer format. The corresponding operation can be given in advance according to the number of the section ID, and the user can freely assign and use the section ID number according to the needs of the application.

The following table shows an example of the initial numbering of a section ID according to the present invention. The following constituent elements are not limited to the order, and all constituent elements are not necessarily included, but may be constituted by some constituent elements.

Section ID operation description 0x0000 Reference Header Root Description An M-unit stream can use multiple reference header sections as needed, and these sections can be further divided into two or more reference headers as needed. Provide the section ID used in the entire M-unit stream in advance
If the M-unit stream uses the reference header, the system must read the section
A section that allows you to determine which section the M-unit stream is using 0x0001 Timestamp Description If the M-unit uses the Constant Time Stamp mode, the section that provides the Constant Time Stamp related information
The information described in this section is valid for M-units corresponding to mu_seqno from start_mu_seqno of this timestamp description to start_mu_seqno-1 of the next timestamp description 0x0002 Multiple MFU Aggregation Description If an M-unit contains more than one MFU, the section referred to by that M-unit
The section and M-unit are coupled to start_mu_seqno and seq_no of the M-unit 0x0003 Dependency Description If there is a dependency relationship between groups of M-units or M-units, a section describing the dependencies 0x0004 to 0x7fff (TBD / Reserved) - 0x8000 ~ 0xFFFF User Defined A section that the user selects and uses randomly according to the application

Here, section_byte_length indicates the size of the section, and may be in units of bytes. Here, the size of the section may include the size of the section ID, the section_byte_length, or the start_mu_seqno field. Also, start_mu_seqno indicates the M-unit position in the M-unit stream to which the corresponding section is applied by the sequence number of the M-unit. Thus, the M-unit of the M-unit stream using the reference header has a sequence number.

no_of_section means the number of all sections used in the M-unit stream. Also, section_ID_used refers to the section ID used in the M-unit stream. At this time, no_of_section and section_ID_used can be used when the section ID is "0x0000 ".

base_CTS is the starting CTS value of the starting M-unit for an M-unit using a constant timestamp mode. CTS_increment is the increment (but in AU) of CTS for M-units using the constant time stamp mode. base_CTS and CTS_increment can be used when the section ID is "0x0001 ".

 no_of_media_fragment_unit means the number of MFUs when one M-unit is composed of two or more MFUs. MFU_byte_offset indicates the byte offset value of the current MFU from the start of the M-unit in the order of the MFUs constituting the M-unit. MFU_byte_size indicates the byte size of the current MFU in the order of the MFUs constituting the M-unit. At this time, no_of_media_fragment_unit and MFU_byte_offset MFU_byte_size can be used when the section ID is "0x0002".

In the above-described exemplary system, the methods are described on the basis of a flowchart as a series of steps or blocks, but the present invention is not limited to the order of the steps, and some steps may occur in different orders . It will also be understood by those skilled in the art that the steps shown in the flowchart are not exclusive and that other steps may be included or that one or more steps in the flowchart may be deleted without affecting the scope of the invention.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

Claims (10)

A packet generation apparatus comprising:
An encapsulating unit for encapsulating a media fragment unit (MFU) to generate a media unit; And
And a packetizer for packetizing the media unit to generate a packet,
Wherein the media fragment unit is divided into units of Asset Units (AUs) that are the smallest data entities to which timings are transmitted. The method according to claim 1,
Wherein the packetizing unit comprises:
Wherein the media unit includes a flag indicating whether the media unit includes timed media data or non-timed media data, and generates the packet. 3. The method of claim 2,
Indicating that the media unit includes timed media data if the value of the flag is 1 and indicating that the media unit includes non-timed media data if the value of the flag is 0, . 3. The method of claim 2,
Wherein the flag has a size of one bit. 3. The method of claim 2,
Wherein the flag is contained in a payload header of the packet. In a packet generation method,
Encapsulating a Media Fragment Unit (MFU) to create a media unit; And
Packetizing the media unit to generate a packet,
Wherein the media fragment unit is divided into units of Asset Units (AUs), which are the smallest data entities to which timings are transmitted. The method according to claim 6,
The packet generation step includes:
Generating a packet by including a flag indicating whether the media unit includes timed media data or non-timed media data, Way. 8. The method of claim 7,
Indicating that the media unit includes timed media data if the value of the flag is 1 and indicating that the media unit includes non-timed media data if the value of the flag is 0 . 8. The method of claim 7,
Wherein the flag has a size of one bit. 8. The method of claim 7,
Wherein the flag is included in a payload header of the packet.

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