SMPTE ST 2082-10-2015 2160-line Source Image and Ancillary Data Mapping for 12G-SDI.pdf

1、 Copyright 2015 by THE SOCIETY OF MOTION PICTURE AND TELEVISION ENGINEERS 3 Barker Avenue, White Plains, NY 10601 (914) 761-1100 Approved February 4, 2015 Table of Contents Page Foreword . 2 Intellectual Property 2 Introduction 2 1 Scope . 4 2 Conformance Notation . 4 3 Normative References . 4 4 Mo

2、de 1: Carriage of 2160-Line Source Image Formats and Ancillary Data 5 4.1 Mapping . 5 4.2 Audio Data . 10 4.3 Payload Identifier . 14 4.4 Multiplex . 17 4.5 Levels of Operation (Informative) 18 5 12G-SDI 10-Bit Multiplex 18 Annex A Bibliography (Informative) . 20 Annex B Ancillary Data Capacity of t

3、he 12G-SDI Interface (Informative) 21 Page 1 of 21 pages SMPTE ST 2082-10:2015 SMPTE STANDARD 2160-line Source Image and Ancillary Data Mapping for 12G-SDI SMPTE ST 2082-10:2015 Page 2 of 21 pages Foreword SMPTE (the Society of Motion Picture and Television Engineers) is an internationally-recognize

4、d standards developing organization. Headquartered and incorporated in the United States of America, SMPTE has members in over 80 countries on six continents. SMPTEs Engineering Documents, including Standards, Recommended Practices, and Engineering Guidelines, are prepared by SMPTEs Technology Commi

5、ttees. Participation in these Committees is open to all with a bona fide interest in their work. SMPTE cooperates closely with other standards-developing organizations, including ISO, IEC and ITU. SMPTE Engineering Documents are drafted in accordance with the rules given in its Standards Operations

6、Manual. SMPTE ST 2082-10 Document was prepared by Technology Committee 32NF. Intellectual Property At the time of publication no notice had been received by SMPTE claiming patent rights essential to the implementation of this Standard. However, attention is drawn to the possibility that some of the

7、elements of this document may be the subject of patent rights. SMPTE shall not be held responsible for identifying any or all such patent rights. Introduction SMPTE ST 2082-10 defines the mapping of various source images and associated ancillary data into a 12 Gb/s nominal SDI bit-serial interface.

8、The general process for creating 12G-SDI is illustrated below in Figure 1. Detailed definitions of how this process applies to each of the modes defined in the scope follow in other sections of this document. 1 2 G - S D I 1 0 - b i t i n t e r f a c e S T 2 0 8 2 - 11 2 G - S D I 1 0 - b i t M u l

9、t i p l e x2 1 6 0 - l i n e I m a g eM u xD i v i s i o n t o S u b I m a g e sS o u r c e I m a g e d a t aS u b I m a g e O n eD a t a S t r e a m T w oD a t a S t r e a m T h r e eD a t a S t r e a m F o u rD a t a S t r e a m F i v eD a t a S t r e a m S i xD a t a S t r e a m S e v e nD a t a

10、S t r e a m E i g h tM a p p i n g o n t o 8 0 - b i t V i r t u a l I n t e r f a c e S u b I m a g e T w oS u b I m a g e T h r e eS u b I m a g e F o u rD a t a S t r e a m O n eFigure 1 Carriage of 2160-line images in a 12G-SDI interface generalized process SMPTE ST 2082-10:2015 Page 3 of 21 pag

11、es Formatting The source images are divided into two or four 1080-line sub images, depending on the format of the source image. The sub images are then mapped onto an 80-bit virtual interface consisting of eight 10-bit data streams. Each 10-bit data stream includes timing and sync words, line number

12、s, cyclic redundancy codes, ancillary data, including audio, and payload identification packets. Multiplex The 80-bit virtual interface is multiplexed onto a 12G-SDI 10-bit interface. The data streams are multiplexed in the order data stream eight, data stream four, data stream six, data stream two,

13、 data stream seven, data stream three, data stream five, data stream oneonto the 12G-SDI Link. SMPTE ST 2082-10:2015 Page 4 of 21 pages 1 Scope This Standard defines the mapping of: Mode 1: 2160-line Source image formats and ancillary data into a 12 Gb/s nominal SDI bit-serial interface This Standar

14、d also defines the carriage of the SMPTE ST 352 payload IDs for the 12 Gb/s SDI interface. It is not necessary for implementations to include support for all formats that are included in this Standard. Implementers should indicate supported formats in commercial publications. 2 Conformance Notation

15、Normative text is text that describes elements of the design that are indispensable or contains the conformance language keywords: “shall“, “should“, or “may“. Informative text is text that is potentially helpful to the user, but not indispensable, and can be removed, changed, or added editorially w

16、ithout affecting interoperability. Informative text does not contain any conformance keywords. All text in this document is, by default, normative, except: the Introduction, any section explicitly labeled as “Informative“ or individual paragraphs that start with “Note:” The keywords “shall“ and “sha

17、ll not“ indicate requirements strictly to be followed in order to conform to the document and from which no deviation is permitted. The keywords, “should“ and “should not“ indicate that, among several possibilities, one is recommended as particularly suitable, without mentioning or excluding others;

18、 or that a certain course of action is preferred but not necessarily required; or that (in the negative form) a certain possibility or course of action is deprecated but not prohibited. The keywords “may“ and “need not“ indicate courses of action permissible within the limits of the document. The ke

19、yword “reserved” indicates a provision that is not defined at this time, shall not be used, and may be defined in the future. The keyword “forbidden” indicates “reserved” and in addition indicates that the provision will never be defined in the future. A conformant implementation according to this d

20、ocument is one that includes all mandatory provisions (“shall“) and, if implemented, all recommended provisions (“should“) as described. A conformant implementation need not implement optional provisions (“may“) and need not implement them as described. Unless otherwise specified, the order of prece

21、dence of the types of normative information in this document shall be as follows: Normative prose shall be the authoritative definition; Tables shall be next; followed by formal languages; then figures; and then any other language forms. 3 Normative References The following standards contain provisi

22、ons that, through reference in this text, constitute provisions of this standard. At the time of publication, the editions indicated were valid. All standards are subject to revision, and parties to agreements based on this standard are encouraged to investigate the possibility of applying the most

23、recent edition of the standards indicated below. SMPTE ST 299-1:2009, 24-Bit Digital Audio Format for SMPTE 292 Bit-Serial Interface SMPTE ST 299-2:2010, Extension of the 24-Bit Digital Audio Format to 32 Channels for 3 Gb/s Bit-Serial Interfaces SMPTE ST 352:2013, Payload Identification Codes for S

24、erial Digital Interfaces SMPTE ST 425-5:2014, Image Format and Ancillary Data Mapping for the Quad Link 3 Gb/s Serial Interface SMPTE ST 2082-10:2015 Page 5 of 21 pages 4 Mode 1: Carriage of 2160-Line Source Image Formats and Ancillary Data In the case of 2160-line mapping, the image formats support

25、ed are defined in Table 1 of SMPTE ST 425-5 “2160-line Source Image Formats”, repeated here for convenience. Table 1 2160-line Source Image Formats Supported (Informative) Reference SMPTE Standard Image Format Signal Format Sampling Structure/pixel Depth Frame Rate Hz ST 2036-1 3840 2160 4:2:2 (YCBC

26、R), 4:2:0 (YCBCR)/10-bit 50, 60/1.001 and 60 Progressive ST 2048-1 4096 2160*2 4:2:2 (YCBCR)/10-bit 48/1.001, 48, 50, 60/1.001 and 60 Progressive ST 2036-1 3840 2160 4:4:4 (RGB) 24/1.001, 24, 25, 30/1.001 and 30 Progressive ST 2048-1 4096 2160*2 4:4:4 (RGB*1), 4:4:4:4 (RGB*1+A)/10-bit ST 2036-1 3840

27、 2160 4:4:4 (YCBCR) ST 2048-1 4096 2160*2 4:4:4 (YCBCR), 4:4:4:4 (YCBCR+A)/10-bit ST 2036-1 3840 2160 4:4:4 (RGB)/12-bit ST 2048-1 4096 2160*2 4:4:4 (RGB*1)/12-bit ST 2036-1 3840 2160 4:4:4 (YCBCR)/12-bit ST 2048-1 4096 2160*2 4:4:4 (YCBCR)/12-bit ST 2036-1 3840 2160 4:2:2 (YCBCR)/12-bit 4:2:0 (YCBC

28、R)/12-bit ST 2048-1 4096 2160*2 4:2:2 (YCBCR)/12-bit ST 2048-1 4096 2160*2 4:2:2:4 (YCBCR+A)/12-bit Notes: *1 In this image format RGB indicates either RGB or RFSGFSBFS. An additional Color VANC packet to describe the FS characteristics is defined by SMPTE ST 2048-1. *2 This is the maximum pixel arr

29、ay, the active image may not fill the maximum array. 4.1 Mapping The source image shall be divided into four sub images in accordance with the 2-sample interleave division method defined in SMPTE ST 425-5 “2160-line image division into four sub images”. The four resulting sub images shall then be ma

30、pped into an 80-bit virtual interface in accordance with the sub image mapping structure numeral 1, 2, 3 or 4 defined in Table 1 “2160-line Source Image Formats” of SMPTE ST 425-5 such that: SMPTE ST 2082-10:2015 Page 6 of 21 pages Sub image 1 is mapped into data stream one and data stream two. Sub

31、image 2 is mapped into data stream three and data stream four. Sub image 3 is mapped into data stream five and data stream six. Sub image 4 is mapped into data stream seven and data stream eight This process is illustrated in the Figure “Mapping Overview for 2160-line Source Images” in SMPTE ST 425-

32、5. The 80-bit virtual interface shall include sync and timing (TRS) words, Cyclic redundancy code (CRC) words, line numbers, HANC and VANC data and time code except audio according to SMPTE ST 425-5 “Level A mapping for 2160-line source images”. Informative Annex B provides information about the amo

33、unt of HANC and VANC data space available in this operating mode. 4.1.1 Mapping Process (Informative) Figure 2 illustrates the process for the carriage of SMPTE ST 2036-1 and SMPTE ST 2048-1 2160-line source image formats in a 12G-SDI interface. D a t a S t r e a m O n eD a t a S t r e a m T w oD a

34、t a S t r e a m T h r e eD a t a S t r e a m F o u r1 2 G - S D I 1 0 - b i t M u l t i p l e xD a t a S t r e a m F i v eD a t a S t r e a m S i xD a t a S t r e a m S e v e nD a t a S t r e a m E i g h t003 8 3 9 /4 0 9 52 1 5 91 21 2 1 21 23 43 4 3 43 41 21 2 1 21 23 43 4 3 43 41 21 2 1 21 23 43

35、4 3 43 4S T 4 2 5 - 5 8 0 - b i t V i r t u a l I n t e r f a c e M a p p i n g2 s a m p l e i n t e r l e a v e S u b -d i v i s i o nS o u r c e I m a g e1 9 2 0 /2 0 4 801 9 1 9 /2 0 4 711 1 2 21 1 2 54 2EAVSAVH A N CD a t aS u b I m a g e 1EAVSAVH A N CD a t aS u b I m a g e 2EAVSAVH A N CD a t

36、aS u b I m a g e 3EAVSAVH A N CD a t aS u b I m a g e 41 2 G - S D I 1 0 - b i t i n t e r f a c e S T 2 0 8 2 - 1M u xFigure 2 Carriage of 2160-line mapping source image formats in a 12G-SDI interface The 2160-line source image is divided into four 1080-line sub images in accordance with the 2 samp

37、le interleave sub-division method referenced in SMPTE ST 425-5 2160-line Mapping. For a 4:2:0 source image, the CB and CR samples in sub images 3 and 4 are set to the value 200h for 10-bit systems and 800h for 12-bit systems. Each 1080-line sub image has the structure as shown in Table 2 “Sub Image

38、Formats”, of SMPTE ST 425-5 repeated here for convenience in Table 2. SMPTE ST 2082-10:2015 Page 7 of 21 pages Table 2 Sub Image Formats (Informative) Source Image Sub Image Reference SMPTE Standard Image Format Reference SMPTE Standard Image Format ST 2036-1 3840 2160 ST 274 1920 1080 ST 2048-1 409

39、6 2160 ST 2048-2 2048 1080 Each sub image is mapped into two 10-bit data streams. Sub image 1 is mapped into data streams one and two. Sub image 2 is mapped into data streams three and four. Sub image 3 is mapped into data streams five and six. Sub image 4 is mapped into data streams seven and eight

40、. Each data stream includes sync and timing (TRS) words, Cyclic redundancy code (CRC) words, line numbers, HANC and VANC data and time code. The eight 10-bit data streams are combined onto an 80-bit virtual interface: 4.1.2 2160-line 80-bit Virtual Interface Multiplex Structure (Informative) The vid

41、eo data words from each sub image are conveyed in the following order in the data streams of the 80-bit virtual interface: Mapping Structure 1: Sub image 1 is mapped into data streams one and two: data stream one: Y0, Y1, Y2, Y3. data stream two: CB0, CR0, CB1, CR1. Sub image 2 is mapped into data s

42、treams three and four: data stream three: Y0, Y1, Y2, Y3. data stream four: CB0, CR0, CB1, CR1. Sub image 3 is mapped into data streams five and six: data stream five: Y0, Y1, Y2, Y3. data stream six: CB0, CR0, CB1, CR1. Sub image 4 is mapped into data streams seven and eight: data stream seven: Y0,

43、 Y1, Y2, Y3. data stream eight: CB0, CR0, CB1, CR1. For a 4:2:0 source images, the 10-bit CB and CR samples in sub images 3 and 4 are set to the value 200h. SMPTE ST 2082-10:2015 Page 8 of 21 pages Mapping Structure 2: Sub image 1 is mapped into data streams one and two: data stream one: G0, R0, G1,

44、 R1. data stream two: A0, B0, A1, B1. Sub image 2 is mapped into data streams three and four: data stream three: G0, R0, G1, R1. data stream four: A0, B0, A1, B1. Sub image 3 is mapped into data streams five and six: data stream five: G0, R0, G1, R1. data stream six: A0, B0, A1, B1. Sub image 4 is m

45、apped into data streams seven and eight: data stream seven: G0, R0, G1, R1. data stream eight: A0, B0, A1, B1. Mapping Structure 3: Bit b9 in every word is the complement of b8. The lists and tables below describe Bits b8 b0 Sub image 1 is mapped into data streams one and two: data stream one: RGB 0

46、 11:9, RGB 0 5:3, RGB 1 11:9, RGB 1 5:3. data stream two: RGB 0 8:6, RGB 0 2:0, RGB 1 8:6, RGB 1 2:0. Sub image 2 is mapped into data streams three and four: data stream three: RGB 0 11:9, RGB 0 5:3, RGB 1 11:9, RGB 1 5:3. data stream four: RGB 0 8:6, RGB 0 2:0, RGB 1 8:6, RGB 1 2:0. Sub image 3 is

47、mapped into data streams five and six: data stream five: RGB 0 11:9, RGB 0 5:3, RGB 1 11:9, RGB 1 5:3. data stream six: RGB 0 8:6, RGB 0 2:0, RGB 1 8:6, RGB 1 2:0. Sub image 4 is mapped into data streams seven and eight: data stream seven: RGB 0 11:9, RGB 0 5:3, RGB 1 11:9, RGB 1 5:3. data stream ei

48、ght: RGB 0 8:6, RGB 0 2:0, RGB 1 8:6, RGB 1 2:0. Mapping Structure 4: Bit b9 in every word is the complement of b8. The lists and tables below describe Bits b8 b0 Sub image 1 is mapped into data streams one and two: data stream one: Bits b8 b6: A0 11:9, A0 5:3, A1 11:9, A1 5:3. Bits b5 b0: Y0 11:6, Y0 5:0, Y1 11:6, Y1 5:0. data stream two: Bits b8 b6: A0 8:6, A0 2:0, A1 8:6, A1 2:0. Bits b5 b0: CB 0 11:6, CB 0 5:0, CR 0 11:6, CR 0