• DocumentCode
    541132
  • Title

    Exploring the distributed video coding in a quality assessment context

  • Author

    Banitalebi, Amin ; Nader-Esfahani, Said

  • Author_Institution
    Wireless Multimedia Signal Process. Lab., Univ. of Tehran, Tehran, Iran
  • fYear
    2010
  • fDate
    4-6 Dec. 2010
  • Firstpage
    695
  • Lastpage
    700
  • Abstract
    In the popular video coding trend, the encoder has the task to exploit both spatial and temporal redundancies present in the video sequence, which is a complex procedure; As a result almost all video encoders have five to ten times more complexity than their decoders. In a video compression process, one of the main tasks at the encoder side is motion estimation which is to extract the temporal correlation between frames. Distributed video coding (DVC) proposed the idea that can lead to low complexity encoders and higher complexity decoders. DVC is a new paradigm in video compression based on the information theoretic ideas of Slepian-Wolf and Wyner-Ziv theorems. Wyner-Ziv coding is naturally robust against transmission errors and can be used for joint source and channel coding. Side Information is one of the key components of the Wyner-Ziv decoder. Better side information generation will result in better functionality of Wyner-Ziv coder. In this paper we proposed a new method that can generate side information with a better quality and thus better compression. We´ve used HVS (human visual system) based image quality metrics as our quality criterion. The motion estimation we´ve used in the decoder is modified due to these metrics such that we could obtain finer side information. The motion compensation is optimized for perceptual quality metrics and leads to better side information generation compared to conventional MSE (mean squared error) or SAD (sum of absolute difference) based motion compensation currently used in the literature. Better motion compensation means better compression.
  • Keywords
    channel coding; data compression; decoding; image sequences; motion estimation; video coding; Slepian-Wolf theorem; Wyner-Ziv theorem; channel coding; distributed video coding; encoder; human visual system; image quality metric; mean squared error; motion compensation; motion estimation; quality assessment context; spatial redundancy; sum of absolute difference; temporal correlation extraction; temporal redundancy; video compression process; video sequence; Complexity theory; Decoding; Encoding; Measurement; Motion estimation; Silicon; Video coding; distributed video coding; motion compensation; structural similarity; visual information fidelity;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Telecommunications (IST), 2010 5th International Symposium on
  • Conference_Location
    Tehran
  • Print_ISBN
    978-1-4244-8183-5
  • Type

    conf

  • DOI
    10.1109/ISTEL.2010.5734112
  • Filename
    5734112