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SWE%20423:%20Multimedia%20Systems

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Title: SWE%20423:%20Multimedia%20Systems


1
SWE 423 Multimedia Systems
  • Chapter 7 Data Compression (7)

2
Outline
  • Introduction to H.261
  • H.261 Image Preparation
  • H.261 Coding Algorithms
  • H.263
  • H.261 H.263 Properties
  • H.261 vs. H.263
  • H.264

3
Introduction to H.261
  • ISDN Integrated Services Digital Network is
    (and was) behind H.261
  • A circuit-switched telephone network system,
    designed to allow digital transmission of voice
    and data over ordinary telephone copper wires.
  • In ISDN, there are two types of channels, B (for
    "Bearer") and D (for "Delta"). B channels are
    used for data (which may include voice), and D
    channels are intended for signaling and control
    (but can also be used for data).
  • In a narrow-band ISDN connection, exactly two
    B-channels and one D-channel is available
  • One or both B channels can transfer video data,
    in addition to speech.
  • This requires that both ends have to use the same
    video data coding schemes

4
Introduction to H.261
  • The primary applications of ISDN were video
    phones and video conferencing.
  • Such dialogue applications require that coding
    and decoding being carried out in real-time.
  • In 1984, Study group XV of CCITT formed a
    committee to draw up a video standard for
    compressing moving pictures
  • The standard, H.261 Video CoDec for Audiovisual
    services at p?64Kbit/s was finalized after 5
    years and got accepted in December 1990.
  • North America adopted it with slight
    modifications
  • Since data rates of p?64 Kbit/s are considered,
    the recommendation was also known as p?64.
  • Maximum combined signal delay is 150 ms

5
H.261 Image Preparation
  • Very precise format, unlike JPEG
  • Refresh frequency at the input must be 30000/1001
    frames/s
  • During encoding, lower frame rates are possible
    (10 or 15 frames/s)
  • Images cannot be presented at the input to the
    coder using interlaced scanning
  • The image is encoded as a luminance signal Y and
    chrominance difference signals Cb, Cr, according
    to the CCIR 601 sub-sampling scheme (211)
  • This was later adopted by MPEG

6
H.261 Image Preparation
  • Two resolution formats are supported, both with
    an aspect ratio of 43
  • Common Intermediate Format (CIF)
  • Optional
  • 352 lines, each with 288 pixels of luminance (Y)
    component
  • As per the (211) requirement, the chrominance
    components are sub-sampled with ....... lines,
    each with ....... Pixels.
  • Quarter CIF (QCIF)
  • All H.261 CoDecs have to implement QCIF
  • Has exactly half the resolution in all components.

7
H.261 Image Preparation
  • H.261 divides the Y, Cb and Cr components into
    blocks of 8?8 pixels
  • A macro block results from combining 4 blocks of
    the Y matrix with 1 block each from the Cb and Cr
    components.
  • A group of blocks consists of 3?11 macro blocks.
    Hence,
  • CIF consists of ...... groups
  • QCIF consists of ....... groups

8
H.261 Coding Algorithms
  • H.261 uses two different modes of coding
  • Intra-frame coding
  • Inter-frame coding
  • H.261 does not specify any criteria for choosing
    one or the other.
  • That decision is taken during encoding

9
H.261 Coding Algorithms
  • Intra-frame coding
  • Considers data from image being coded
  • Like JPEG, each block of 8?8 pixels is
    transformed into 64 coefficients using DCT.
  • DC coefficients are quantized differently than AC
    coefficients
  • Entropy encoding using variable-length code words
    is then performed.

10
H.261 Coding Algorithms
  • Inter-frame coding
  • Considers data from other images
  • A prediction method is used to find the most
    similar macro block in the preceding image.
  • Motion vector is the relative position of the
    previous macro block w.r.t. the current macro
    block
  • According to H.261, the encoder needs not
    determine a motion vector, thus may only consider
    differences between macro blocks located at the
    same position in successive images.
  • The motion vector is processed and entropy
    encoded using variable-length code words
  • The DPCM-coded macro block is processed and
    transformed using DCT if and only if its value
    exceeds a certain threshold value, linearly
    quantized, and entropy encoded using
    variable-length code words
  • An optical low pass filter can be optionally
    inserted between the DCT transformation and
    entropy encoding to delete any remaining
    high-frequency noise.

11
H.263
  • Developed in 1996 to replace H.261 for many
    applications
  • Designed for low bit rate transmission, but also
    suitable for higher bit rates applications
  • Provides one of the most efficient video
    compression techniques available.

12
H.263
  • Inclusion of four negotiable options to improve
    performance (achieving same quality as H.261 with
    less than half as many bits)
  • Syntax-based arithmetic coding
  • Defines the use of arithmetic coding instead of
    variable length coding
  • Forward and backward frame prediction
  • Can increase frame rate without changing the bit
    rate by coding two images as one unit.
  • Unrestricted Motion Vectors
  • Makes it possible for motion vectors to point
    outside image boundaries.
  • Useful for small images with motion in the
    direction of edges
  • Advanced Prediction
  • Uses the overlapped block motion compensation
    (OBMC) technique for P-frame luminance.
  • An algorithm that obtains motion vectors from
    blocks next to the current macro block and uses
    them with the current macro block to achieve a
    more accurate predication and a smaller bit
    stream.
  • Requires the use of unrestricted motion vectors.

13
H.261 H.263 Properties
  • The data stream contains information for error
    correction, although the use of external error
    correction standards (e.g. H.223) is recommended.
  • Each image in H.261 includes a 5-bit image number
    that can be used as a temporal reference. H.263
    uses 8-bit image numbers
  • During decoding, a command can be sent to the
    decoder to freeze the last video frame.
  • It is possible to switch between still images and
    moving images using an additional command sent by
    the coder.

14
H.261 vs. H.263
  • Use similar coding algorithms
  • With some enhancements and error correction in
    H.263
  • H.263 uses half pixel precision for motion
    compensation, while H.261 uses full pixel
    precision with loop filter.
  • Some parts of the hierarchical structure of the
    data stream are now optional, so the codec can be
    configured for a lower data rate or better error
    recovery.
  • Inclusion of four negotiable options to improve
    performance (achieving same quality as H.261 with
    less than half as many bits)
  • Unrestricted Motion Vectors,
  • Syntax-based arithmetic coding,
  • Advance prediction, and
  • Forward and backward frame prediction
  • similar to MPEGs P and B frames.
  • H.263 supports three more resolutions (SQCIF,
    4CIF, and 16CIF) in addition to the two supported
    by H.261 (QCIF and CIF)
  • SQCIF is approximately half the resolution of
    QCIF.
  • 4CIF and 16CIF are 4 and 16 times the resolution
    of CIF respectively.
  • The support of 4CIF and 16CIF means the codec
    could then compete with other higher bitrate
    video coding standards such as the MPEG
    standards.
  • Check http//www-mobile.ecs.soton.ac.uk/peter/h263
    /h263.html for samples

15
H.264
  • H.264 was finalized and published in March 2005
    and represents an evolution of the existing video
    coding standards (H.261,H.262, and H.263)
  • It was developed in response to the growing need
    for higher compression of moving pictures for
  • various applications such as videoconferencing,
    digital storage media, television broadcasting,
    Internet streaming, and communication and enable
    the use of the coded video representation in a
    flexible manner for a wide variety of network
    environments.
  • It also allows motion video to be manipulated as
    a form of computer data and to be stored on
    various storage media, transmitted and received
    over existing and future networks and distributed
    on existing and future broadcasting channels.

16
H.264
  • The revision contains modifications of the video
    coding standard to
  • add four new profiles, High, High 10, High 422,
    and High 444 profiles
  • improve video quality capability
  • extend the range of applications addressed by the
    standard (for example, by including support for a
    greater range of picture sample precision and
    higher-resolution chroma formats).
  • define new types of supplemental data has been
    specified to further broaden the applicability of
    the video coding standard.
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