Faculty of Information Technology, BUT

Course details

Graphic and Multimedia Processors

GMU Acad. year 2011/2012 Winter semester 5 credits

Current academic year

Colour models. Principles of 2D/3D graphics. Algorithms for computer graphics and computational complexity. First and second generation of graphical processors - TMS34010/20, TIGA, Trio64V+, Intel i860, Savage3D, Intel740, Permedia, RIVA TNT. Organization of video memory. Parallelization of geometry engine. Multiprocessor raster architectures - image and object parallelization. Texture mapping and compression, pixel interpolation. Graphical multiprocessors. GPGPU.  Quantization. Predictive coding. Cosine and wavelet transform. Motion compensation and hybrid coding. Subband coding and vector quantization. Standards for image, video and audio transmission - JPEG, ITU-T H.261, MPEG-1, 2, 4, 7. Signal processors. Multimedia processors - VLIW, Mpact, CyberPro. Multimedia extensions of instruction set x86 - MMX, SIMD. Game consoles.


Language of instruction



Credit+Examination (written)

Time span

26 hrs lectures, 8 hrs pc labs, 18 hrs projects

Assessment points

60 exam, 40 projects




Subject specific learning outcomes and competences

Students will get knowledge of hardware support for graphical and multimedia operations and programming them in OpenGL and CUDA environment.

Learning objectives

To inform the students about hardware support and implementation of graphical amultimedia operations and making use of OpenGL language for image information processing. Newly CUDA tool was adopted for programming GPGPU.


Study literature

  • Lecture notes in e-format.

Fundamental literature

  • Foley J.D., van Dam A., Feiner S.K., Hughes J.F.: Computer Graphics, Principles and Practice, Addison Wesley, 1990
  • Rao K.R., Hwang J.J.: Techniques & Standards for Image, Video & Audio Coding, Prentice Hall, 1996

Syllabus of lectures

  • Color model, CUDA, 2D graphics.
  • 3D graphics, complexity, graphical accelerators.
  • Video memory, graphical processors.
  • Parallelization of geometry and rasterization stage.
  • SGI architecture, texture mapping and compression, pixel interpolation.
  • Graphic multiprocessors, GPGPU. 
  • Kvantizing and prediction coding.
  • Cosine and wavelet transform.
  • Motion compensation, subband coding.
  • JPEG, ITU-T H.261, MPEG-1.
  • MPEG-2, -4, -7.
  • Signal processors.
  • Multimedia processors, instruction sets. Game consoles.

Syllabus of computer exercises

  • Introduction to OpenGL, GLUT and CUDA.
  • 2D Graphics.
  • Display lists, transformation and matrix stack, animation.
  • Texturing.
  • Fogg, mip-mapping.
  • Evaluators, Bézier surfaces, NURBS and quadrics.
  • Project presentation!!! (during computer laboratories)

Syllabus - others, projects and individual work of students

Individual project assignment.

Progress assessment

Passing labs and finishing the project.

Controlled instruction

Passing labs and finishing the project.

Exam prerequisites

Passing labs and finishing the project.

Course inclusion in study plans

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