Course details

Image Processing

ZPO Acad. year 2015/2016 Summer semester 5 credits

Current academic year

Introduction to image processing, image acquiring, point and discrete image transforms, linear image filtering, image distortions, types of noise, optimal image filtering, non-linear image filtering, watermarks, edge detection, segmentation, motion analysis, loseless and lossy image compression

Guarantor

Language of instruction

Czech, English

Completion

Examination

Time span

  • 26 hrs lectures
  • 26 hrs projects

Department

Subject specific learning outcomes and competences

The students will get acquainted with the image processing basics theory (transformations, filtration, noise reduction, etc.). They will learn how to apply such knowledge on real examples of image processing tasks. They will also get acquainted with "higher" imaging algorithms. Finally, they will learn how to practically program image processing applications through projects.

Students will improve their teamwork skills and in exploitation of "C" language.

Learning objectives

To get acquainted with the image processing basics theory (transformations, filtration, noise reduction, etc.). To learn how to apply such knowledge on real examples of image processing tasks. To get acquainted with "higher" imaging algorithms. To learn kow to practically program image processing applications through projects.

Recommended prerequisites

Prerequisite knowledge and skills

The C programming language and fundamentals of computer graphics.

Study literature

  • Hlaváč, V., Šonka, M.: Počítačové vidění, GRADA, 1992, ISBN 80-85424-67-3

Fundamental literature

  • Hlaváč, V., Šonka, M.: Počítačové vidění, GRADA 1992, ISBN 80-85424-67-3
  • Jahne, B.: Handbook of Computer Vision and Applications, Academic Press, 1999, ISBN 0-12-379770-5
  • Russ, J.C.: The Image Processing Handbook, CRC Press 1995, ISBM 0-8493-2516-1

Syllabus of lectures

  1. Introduction to image processing
  2. Image data acquiring
  3. Point image transforms
  4. Discrete image transforms
  5. Linear image filtering
  6. Image distortion, types of noise
  7. Optimal filtering
  8. Nonlinear image filtering
  9. Watermarks
  10. Edge detection, segmentation
  11. Movement analysis
  12. Image compression, lossy, looseless
  13. Future of image processing

Progress assessment

Study evaluation is based on marks obtained for specified items. Minimimum number of marks to pass is 50.

Controlled instruction

Mid-term test, individual project.

Course inclusion in study plans

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