1. Overview of the H.264/AVC Video Coding Standard ThomasWiegand, Gary J. Sullivan, Gisle Bj ø ntegaard, and Ajay Luthra IEEE TRANSACTIONS ON CIRCUITS AND SYSTEMS FOR VIDEO TECHNOLOGY, VOL. 13, NO. 7, JULY 2003

2. Outline  Overview of the technical features of H.264/AVC  Profiles and Levels

3. Goals of the H.264/AVC  Video Coding Experts Group (VCEG), ITU-T SG16 Q.6 H.26L project (early 1998) Target – double the coding efficiency in comparison to any other existing video coding standards for a broad variety applications. H.261, H.262 (MPEG-2), H.263 (H.263+, H.263++)

4. Scope of video coding standardization Pre-ProcessingEncoding Decoding Post-Processing & Error recovery Source Destination Scope of Standard

5. Applications on H.264/AVC standard  Broadcast over cable, satellite, cable modem, DSL, terrestrial, etc.  Interactive or serial storage on optical and magnetic devices, DVD, etc.  Conversational services over ISDN, Ethernet, LAN, DSL, wireless and mobile networks, modems, etc. or mixtures of these.  Video-on-demand or multimedia streaming services over ISDN, cable modem, DSL, LAN, wireless networks, etc.  Multimedia messaging services (MMS) over ISDN, DSL, ethernet, LAN, wireless and mobile networks, etc.

6. Structure of H.264/AVC video encoder Control Data Video Coding Layer Data Partitioning Network Abstraction Layer H.320MP4FFH.323/IPMPEG-2Etc. Coded Macroblock Coded Slice/Partition

7. Design feature highlights (1) — improved on prediction methods  Variable block-size motion compensation with small block sizes A minimum luma motion compensation block size as small as 4×4.  Quarter-sample-accurate motion compensation First found in an advanced profile of the MPEG- 4 Visual (part 2) standard, but further reduces the complexity of the interpolation processing compared to the prior design.

8. Design feature highlights (2) — improved on prediction methods  Motion vectors over picture boundaries First found as an optional feature in H.263 is included in H.264/AVC.  Multiple reference picture motion compensation  Decoupling of referencing order from display order (X)IBBPBBPBBP … => IPBBPBBPBB … Bounded by a total memory capacity imposed to ensure decoding ability. Enables removing the extra delay previously associated with bi-predictive coding.

9. Design feature highlights (3) — improved on prediction methods  Decoupling of picture representation methods from picture referencing capability Ｂ－ frame could not be used as references for prediction Referencing to closest pictures  Weighted prediction A new innovation in H.264/AVC allows the motion-compensated prediction signal to be weighted and offset by amounts specified by the encoder. For scene fading

10. Design feature highlights (4) — improved on prediction methods  Improved “ skipped ” and “ direct ” motion inference Inferring motion in “ skipped ” areas => for global motion Enhanced motion inference method for “ direct ”

11. Design feature highlights (5) — improved on prediction methods  Directional spatial prediction for intra coding Allowing prediction from neighboring areas that were not coded using intra coding Something not enabled when using the transform-domain prediction method found in H.263+ and MPEG-4 Visual

12. Design feature highlights (6) — improved on prediction methods  In-the-loop deblocking filtering Building further on a concept from an optional feature of H.263+ The deblocking filter in the H.264/AVC design is brought within the motion- compensated prediction loop

13. Design feature highlights (7) — other parts  Small block-size transform The new H.264/AVC design is based primarily on a 4×4 transform. Allowing the encoder to represent signals in a more locally-adaptive fashion, which reduces artifacts known colloquially as “ ringing ”.

14. Design feature highlights (8) — other parts  Hierarchical block transform Using a hierarchical transform to extend the effective block size use for low-frequency chroma information to an 8×8 array Allowing the encoder to select a special coding type for intra coding, enabling extension of the length of the luma transform for low-frequency information to a 16×16 block size

15. Design feature highlights (9) — other parts  Short word-length transform While previous designs have generally required 32-bit processing, the H.264/AVC design requires only 16-bit arithmetic.  Exact-match inverse transform Building on a path laid out as an optional feature in the H.263++ effort, H.264/AVC is the first standard to achieve exact equality of decoded video content from all decoders. Integer transform

16. Design feature highlights (10) — other parts  Arithmetic entropy coding While arithmetic coding was previously found as an optional feature of H.263, a more effective use of this technique is found in H.264/AVC to create a very powerful entropy coding method known as CABAC (context-adaptive binary arithmetic coding)

17. Design feature highlights (11) — other parts  Context-adaptive entropy coding CAVLC (context-adaptive variable- length coding) CABAC (context-adaptive binary arithmetic coding)

18. Design feature highlights (12) — Robustness to data errors/losses and flexibility for operation over a variety of network environments  Parameter set structure The parameter set design provides for robust and efficient conveyance header information  NAL unit syntax structure Each syntax structure in H.264/AVC is placed into a logical data packet called a NAL unit

19. Design feature highlights (13) — Robustness to data errors/losses and flexibility for operation over a variety of network environments  Flexible slice size Unlike the rigid slice structure found in MPEG-2 (which reduces coding efficiency by increasing the quantity of header data and decreasing the effectiveness of prediction), slice sizes in H.264/AVC are highly flexible, as was the case earlier in MPEG-1.

20. Design feature highlights (14) — Robustness to data errors/losses and flexibility for operation over a variety of network environments  Flexible macroblock ordering (FMO) Significantly enhance robustness to data losses by managing the spatial relationship between the regions that are coded in each slice  Arbitrary slice ordering (ASO) sending and receiving the slices of the picture in any order relative to each other first found in an optional part of H.263+ can improve end-to-end delay in real-time applications, particularly when used on networks having out-of-order delivery behavior

21. Design feature highlights (15) — Robustness to data errors/losses and flexibility for operation over a variety of network environments  Redundant pictures Enhance robustness to data loss A new ability to allow an encoder to send redundant representations of regions of pictures

22. Design feature highlights (15) — Robustness to data errors/losses and flexibility for operation over a variety of network environments  Data Partitioning Allows the syntax of each slice to be separated into up to three different partitions for transmission, depending on a categorization of syntax elements This part of the design builds further on a path taken in MPEG-4 Visual and in an optional part of H.263++. The design is simplified by having a single syntax with partitioning of that same syntax controlled by a specified categorization of syntax elements.

23. Design feature highlights (16) — Robustness to data errors/losses and flexibility for operation over a variety of network environments  SP/SI synchronization/switching pictures A new feature consisting of picture types that allow exact synchronization of the decoding process of some decoders with an ongoing video stream produced by other decoders without penalizing all decoders with the loss of efficiency resulting from sending an I picture Enable switching a decoder between different data rates, recovery from data losses or errors, as well as enabling trick modes such as fast- forward, fast-reverse, etc.

24. NAL (Network Abstraction Layer) Control Data Video Coding Layer Data Partitioning Network Abstraction Layer H.320MP4FFH.323/IPMPEG-2Etc. Coded Macroblock Coded Slice/Partition

25. NAL (Network Abstraction Layer)  Designed in order to provide “ network friendliness ”  facilitates the ability to map H.264/AVC VCL data to transport layers such as: RTP/IP for any kind of real-time wire-line and wireless Internet services (conversational and streaming); File formats, e.g., ISO MP4 for storage and MMS; H.32X for wireline and wireless conversational services; MPEG-2 systems for broadcasting services, etc.

26. Key concepts of NAL  NAL Units  Byte stream and Packet format uses of NAL units  Parameter sets  Access units

27. NAL units payload 1 byte header Integer number of bytes Interleaved as necessary with emulation prevention bytes, which are bytes inserted with a specific value to prevent a particular pattern of data called a start code prefix from being accidentally generated inside the payload. The NAL unit structure definition specifies a generic format for use in both packet-oriented and bitstream-oriented transport systems, and a series of NAL units generated by an encoder is referred to as a NAL unit stream.

28. NAL units in byte-stream format use  E.g., H.320 and MPEG-2/H.222.0 systems require delivery of the entire or partial NAL unit stream as an ordered stream of bytes or bits. Each NAL unit is prefixed by a specific pattern of three bytes called a start code prefix. payload

29. NAL units in packet-transport system use  E.g., internet protocol/RTP systems The inclusion of start code prefixes in the data would be a waste of data carrying capacity, so instead the NAL units can be carried in data packets without start code prefixes. payload

30. VCL and no-VCL NAL units  VCL NAL units The data that represents the values of the samples in the video pictures  Non-VCL NAL Any associated additional information such as parameter sets (important header data that can apply to a large number of VCL NAL units) and supplemental enhancement information (timing information and other supplemental data that may enhance usability of the decoded video signal but are not necessary for decoding the values of the samples in the video pictures).

31. Parameter Sets (1)  A parameter set is supposed to contain information that is expected to rarely change and offers the decoding of a large number of VCL NAL units.

32. Parameter Sets (2)  Two types of parameter sets: Sequence parameter sets  Apply to a series of consecutive coded video pictures called a coded video sequence; Picture parameter sets  Apply to the decoding of one or more individual pictures within a coded video sequence.

33. Parameter Sets (3) The Structure VCL NAL unit Picture parameter set Identifier to Picture parameter set Sequence parameter set Identifier to Sequence parameter set Non VCL NAL unit

34. Parameter Sets (4) Transmission VCL NAL unitNon VCL NAL unit VCL NAL unit In-band Out of band

35. Parameter set use with reliable “out-of- band” parameter set exchange H.264/AVC Encoder NAL unit with VCL Data encoded with PS#3 (address in Slice Header ) H.264/AVC Decoder 123321 Reliable Parameter Set Exchange Parameter Set #3 Video format PAL Entr. Code CABAC …

36. Access Units  A set of NAL units in a specified form is referred to as an access unit. access unit delimiter SEI primary coded picture redundant coded picture end of sequence end of stream end start SupplementalEnhancementInformation VCL NAL units slices or slice data partitions

37. Coded Video Sequences  A coded video sequence consists of a series of access units that are sequential in the NAL unit stream and use only one sequence parameter set.  Can be decoded independently  Start with an instantaneous decoding refresh (IDR) – Intra picture.  A NAL unit stream may contain one or more coded video sequences.

38. Motion Estimation Frame Memory Motion Compensation DCTQ IQ IDCT Clipping VLC - output bitstream input video De-blocking Filter Intra- Prediction Intra / inter VCL (Video Coding Layer) Decoder 16×16 macroblocks output video YCbCr Color Space and 4:2:0 Sampling

39. Pictures, Frames, and Fields ∆t∆t Interlaced Frame (Top Field First) Progressive Frame Top Field Bottom Field

40. Slices and Slice Groups (1) Slice #0 Slice #1 Slice #2 Subdivision of a picture into slices when not using FMO. (Flexible Macroblock Ordering)

41. Slices and Slice Groups (2) Slice Group #2 Subdivision of a QCIF frame into slices utilizing FMO. Slice Group #1 Slice Group #0 Slice Group #1

42. Slice coding types  I Slice  P Slice  B Slice  SP Slice Switching P slice efficient switching between different pre-coded pictures becomes possible.  SI Slice Switching I slice Allowing an exact match of a macroblock in an SP slice for random access and error recovery purposes.

43. Adaptive Frame/Field Coding Operation  Three modes can be chosen adaptively for each frame in a sequence. Frame mode Field mode Frame mode / Field coded  For a frames consists of mixed moving regions The frame/field encoding decision can be made for each vertical pair of macroblocks (a 16×32 luma region) in a frame. Macroblock-adaptive frame/field (MBAFF) Picture-adaptive frame/field (PAFF) 16% ~ 20% save over frame-only for ITU-R 601 “ Canoa ”, “ Rugby ”, etc.

44. Macroblock-adaptive frame/field (MBAFF) A Pair of Macroblocks in Frame Mode Top/Bottom Macroblocks in Field Mode

45. PAFF vs MBAFF  The main idea of MBAFF is to preserve as much spatial consistency as possible.  In MBAFF, one field cannot use the macroblocks in the other field of the same frame as a reference for motion prediction.  PAFF coding can be more efficient than MBAFF coding in the case of rapid global motion, scene change, or intra picture refresh.  MBAFF was reported to reduce bit rates 14 ~ 16% over PAFF for ITU-R 601 (Mobile and Calendar, MPEG-4 World News)

46. Intra-Frame Prediction (1)  Intra 4×4 Well suited for coding of parts of a picture with significant detail.  Intra_16×16 together with chroma prediction More suited for coding very smooth areas of a picture. 4 prediction modes  I_PCM Bypass prediction and transform coding and send the values of the encoded samples directly

47. Intra-Frame Prediction (2)  In H.263+ and MPEG-4 Visual Intra prediction is conduced in the transform domain  In H.264/AVC Intra prediction is always conducted in the spatial domain

48. Intra-Frame Prediction (3)

49. Intra-Frame Prediction (4) Across slice boundaries is not allowed.

50. Inter-Frame Prediction in P slices (1) Segmentations of the macroblock MB Types 8x8 Types 16 88 8 88 8 88 8 48 4 44 4 4 8 8 www.vcodex.comwww.vcodex.com H.264 / MPEG-4 Part 10 : Inter Prediction www.vcodex.com *P_Skip

51. Inter-Frame Prediction in P slices (2) The accuracy of motion compensation CD AB E KLMNOP FGHIJ TU RS ccddeeff aa bb gg hh bac efg ijk pqr d h n m s b 1 =(E-5F+20G+20H-5I+J) h 1 =(A-5C+20G+20M-5R+T) b=(b 1 +16) >> 5 h=(h 1 +16) >> 5 ---------- j 1 =cc-5dd+20h 1 +20m 1 -5ee+ff j = (j 1 +512) >> 10 ---------- a=(G+b+1) >> 1 e=(b+h+1) >> 1 clipped to 0~255 clipped to 0~255

52. Inter-Frame Prediction in P slices (3) Multiframe motion-compensated prediction ∆=1 ∆=2 ∆=4 Current Picture 4 Prior Decoded Pictures As Reference

53. Inter-Frame Prediction in B slices  Other pictures can reference pictures containing B slices  Weighted average of two distinct motion- compensated prediction  Utilizing two distinct lists of reference pictures (list0, list1)  4 prediction types list0, list1, bi-predictive, direct prediction, B_Skip  For each partition, the prediction type can be chosen separately.

54. Transform, Scaling, and Quantization(1)  4×4 DCT Integer transform matrix H = 11 1 1 21 -1 -2 1 -1 -1 1 1 -2 2 -1

55. Transform, Scaling, and Quantization(2) Repeated transforms  Intra_16×16, chroma intra modes are intend coding for smooth areas  The DC coefficients undergo a second transform with the results that we have transform coefficients covering the whole macroblock 01 23 0001 1011 Repeat transform for chroma blocks indices correspond to the indices of 2×2 inverse Hadamard transform

56. Transform, Scaling, and Quantization(3)  52 values  An increase of 1in quantization parameter means an increase of quantization step size by approximately 12% (an increase of 6 means an increase of quantization step size by exactly a factor of 2)  A change of step size by approximately 12% also means roughly a reduction of bit rate by approximately 12%

57. Transform, Scaling, and Quantization(4)  Scanning order Zig-zag scan For 2×2 DC coefficients of the chroma component  Raster-scan order  All inverse transform operations in H.264/AVC can be implemented using only additions and bit-shifting operations of 16-bit integer values  Only 16-bit memory accesses are needed for a good implementation of the forward transform and quantization process in the encoder

58. Entropy Coding  Two methods of entropy coding are suppoted An exp-Golomb code - A a single infinite-extent codeword table for all syntax elements For transmitting the quantized transform coefficients  Context-Adaptive Variable Length Coding (CAVLC)

59. CAVLC (1)  The number of nonzero quantized coefficients ( N ) and the actual size and position of the coefficients are coded separately 7, 6, -2, 0, -1, 0, 0, 1, 0, 0, 0, 0, 0, 0,0,0. 1)Number of Nonzero Coefficients (N) and “ Trailing 1s ” T 1s = 2, N =5, These two values are coded as a combined event. One out of 4 VLC tables is used based on the number of coefficients in neighboring blocks.

60. CAVLC (2) 7, 6, -2, 0, -1, 0, 0, 1, 0, 0, 0, 0, 0, 0,0,0. 2) Encoding the Value of Coefficients For T 1s, only sign need to be coded. Coefficient values are coded in reverse order: -2, 6, … A starting VLC is used for -2, and a new VLC may be used based on the just coded coefficient. In this way adaptation is obtained in the use of VLC tables, Six exp-Golomb code tales are available for this adaptation.

61. CAVLC (3) 7, 6, -2, 0, -1, 0, 0, 1, 0, 0, 0, 0, 0, 0,0,0. 3) Sign Information For T 1s, this is sent as single bits. For the other coefficients, the sign bit is included in the exp-Golomb codes

62. CAVLC (4) 4) TotalZeroes The number of zeros between the last nonzero coefficient of the scan and its start. TotalZeroes = 3 N=5, => the number must in the range 0-11, 15 tables are available for N in the range 1-15. (If N=16 there is no zero coefficient.) 7, 6, -2, 0, -1, 0, 0, 1, 0, 0, 0, 0, 0, 0,0,0. 5) RunBefore In this example it must be specified how the 3 zeros are distributed. The number of 0 s before the last coefficient is coded. 2, => range:0-3 => a suitable VLC is used. 1, => range:0-1

63. CAVLC vs CABAC  To efficiency of entropy coding can be improved further if the Context-Adaptive Binary Arithmetic Coding (CABAC) is used.  Compared to CAVLC, CABAC typically provides a reduction in bit rate between 5%~15%.  The highest gains are typically obtained when coding interlaced TV signals.

64. In-Loop Deblocking filter p0p0 p1p1 p2p2 q0q0 q1q1 q2q2 4×4 block edge Time to apply deblocking filter.For p 0 and q 0 : 1.| p 0 -q 0 |<α( QP ) 2.| p 1 -p 0 |<β( QP ) 3.| q 1 -q 0 |<β( QP ).For p 1 and q 1 : | p 2 -p 0 |<β( QP ) or | q 2 q 0 |< β( QP ) *The filter reduces the bit rate typically by 5%~10%

65. Hypothetical Reference Decoder  In H.264/AVC HRD specifies operation of two buffers: The coded picture buffer (CPB)  Modeling the arrival and removal time of the coded bits. The decoded picture buffer (DPB)  Similar in spirit to what MPEG-2 had, but is more flexible in support at a variety of bit rates without excessive delay.

66. Profiles and Levels  Baseline, Main, and Extended  Baseline supports all features in H.264/AVC except: Set 1: B slices, weighted prediction, CABAC, field coding, and picture or macroblock adaptive switching between frame and field coding. Set 2: SP/SI slices, and slice data partitioning.

67. H.264/AVC Profiles Baseline Main Extended Set 1 Set 2 CAVLC FMO, ASO, redundant pictures

68. Conclusions  Some important differences relative to prior standards. Enhanced motion-prediction capability Use of a small block-size exact – match transform Adaptive in-loop deblocking filter Enhanced entropy coding methods  When used well together, a approximately 50% bit rate savings for equivalent perceptual quality relative to the performance of prior standards.