Entry Seiler:1996:IVR from dectechj.bib

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BibTeX entry

@Article{Seiler:1996:IVR,
  author =       "Larry D. Seiler and Robert A. Ulichney",
  title =        "Integrating Video Rendering into Graphics Accelerator
                 Chips",
  journal =      j-DEC-TECH-J,
  volume =       "7",
  number =       "4",
  pages =        "76--88",
  month =        mar,
  year =         "1996",
  CODEN =        "DTJOEL",
  ISSN =         "0898-901X",
  bibdate =      "Thu Mar 20 18:15:43 MST 1997",
  bibsource =    "http://www.math.utah.edu/pub/tex/bib/dectechj.bib",
  URL =          "ftp://ftp.digital.com/pub/Digital/info/DTJ/v7n4/Integrating_Video_Rendering_in_20apr1996DTJK05P8.ps;
                 http://www.digital.com:80/info/DTJK05;
                 http://www.digital.com:80/info/DTJK05/DTJK05AH.HTM;
                 http://www.digital.com:80/info/DTJK05/DTJK05P8.PS;
                 http://www.digital.com:80/info/DTJK05/DTJK05PF.PDF;
                 http://www.digital.com:80/info/DTJK05/DTJK05SC.TXT",
  abstract =     "The fusion of multimedia and traditional computer
                 graphics has long been predicted but has been slow to
                 happen. The delay is due to many factors, including
                 their dramatically different data type and bandwidth
                 requirements. Digital has designed a pair of related
                 graphics accelerator chips that integrate video
                 rendering primitives with two-dimensional and
                 three-dimensional synthetic graphics primitives. The
                 chips perform one-dimensional filtering and scaling on
                 either YUV or RGB source data. One implementation
                 dithers YUV source data down to 256 colors. The other
                 converts YUV to 24-bit RGB, which is then optionally
                 dithered. Both chips leave image decompression to the
                 CPU. The result is significantly faster frame rates at
                 higher video quality, especially for displaying
                 enlarged images. The paper compares the implementation
                 cost of various design alternatives and presents
                 performance comparisons with software image
                 rendering.",
  acknowledgement = ack-nhfb,
  classcodes =   "B6140C (Optical information, image and video signal
                 processing); B6220F (ISDN and multimedia terminal
                 equipment); B1265F (Microprocessors and
                 microcomputers); C5135 (Digital signal processing
                 chips); C6130B (Graphics techniques); C5540 (Terminals
                 and graphic displays); C6130M (Multimedia); C5260
                 (Digital signal processing)",
  keywords =     "1D filtering; 1D scaling; bandwidth requirements;
                 colour graphics; computer graphic equipment; data
                 conversion; data types; DEC; DEC computers; design
                 alternatives; digital signal processing chips;
                 dithering; enlarged; frame rates; graphics accelerator
                 chips; image decompression; image display;
                 implementation costs; multimedia; multimedia systems;
                 performance comparisons; rendering (computer graphics);
                 RGB source data; software image rendering; source data;
                 synthetic graphics primitives; video quality; video
                 rendering primitives; video signal processing; YUV",
  treatment =    "P Practical",
}

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