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Computer Graphics & Image Processing Chapter # 8 Image compression

Computer Graphics & Image Processing Chapter # 8 Image compression. ALI JAVED Lecturer SOFTWARE ENGINEERING DEPARTMENT U.E.T TAXILA Email:: ali.javed@uettaxila.edu.pk Office Room #:: 7. Background. Principal objective: To minimize the number of bits required to represent an image.

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Computer Graphics & Image Processing Chapter # 8 Image compression

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  1. Computer Graphics & Image Processing Chapter # 8 Image compression

  2. ALI JAVED Lecturer SOFTWARE ENGINEERING DEPARTMENT U.E.T TAXILA Email:: ali.javed@uettaxila.edu.pk Office Room #:: 7

  3. Background Principal objective: To minimize the number of bits required to represent an image. Applications Transmission: Broadcast TV via satellite, military communications via aircraft, teleconferencing, computer communications etc. Storage: Educational and business documents, medical images (CT, MRI and digital radiology), motion pictures, satellite images, weather maps, geological surveys, e.t.c)

  4. Overview Image data compression methods fall into two common categories: • Information preserving compression • Especial for image archiving (storage of legal or medical records) • Compress and decompress images without losing information II. Lossy image compression • Provide higher levels of data reduction • Result in a less than perfect reproduction of the original image • Applications: –broadcast television, videoconferencing

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  6. Data vs. information Data is not the same thing as information Data are the means to convey information; various amounts of data may be used to represent the same amount of information Part of data may provide no relevant information: data redundancy The amount of data can be much larger expressed than the amount of information. 6

  7. Data Redundancy • Data that provide no relevant information=redundant data or redundancy. • Image compression techniques can be designed by reducing or eliminating the Data Redundancy • Image coding or compression has a goal to reduce the amount of data by reducing the amount of redundancy.

  8. Data Redundancy

  9. Data Redundancy Three basic data redundancies • Coding Redundancy • Interpixel Redundancy • Psychovisual Redundancy

  10. Coding Redundancy A natural m-bit coding method assigns m-bit to each gray level without considering the probability that gray level occurs with: Very likely to contain coding redundancy Basic concept: • Utilize the probability of occurrence of each gray level (histogram) to determine length of code representing that particular gray level: variable-length coding. • Assign shorter code words to the gray levels that occur most frequently or vice versa.

  11. Coding Redundancy

  12. Coding Redundancy (Example)

  13. Coding Redundancy (Example)

  14. Coding Redundancy (Example) 14

  15. Interpixel Redundancy • Caused by High Interpixel Correlations within an image, i.e., gray level of any given pixel can be reasonably predicted from the value of its neighbors (information carried by individual pixels is relatively small) spatial redundancy, geometric redundancy, interframe redundancy (in general, interpixel redundancy ) • To reduce the interpixel redundancy, mapping is used. The mapping scheme can be selected according to the properties of redundancy. • An example of mapping can be to map pixels of an image: f(x,y) to a sequence of pairs: (g1,r1), (g2,r2), ..., (gi,ri), .. gi: ith gray level ri: run length of the ith run

  16. Interpixel Redundancy (Example)

  17. Psychovisual Redundancy • The eye does not respond with equal sensitivity to all visual information. • Certain information has less relative importance than other information in normal visual processing psychovisually redundant (which can be eliminated without significantly impairing the quality of image perception). • The elimination of psychovisually redundant data results in a loss of quantitative information lossy data compression method. • Image compression methods based on the elimination of psychovisually redundant data (usually called quantization) are usually applied to commercial broadcast TV and similar applications for human visualization.

  18. Psychovisual Redundancy

  19. Psychovisual Redundancy 19

  20. Psychovisual Redundancy

  21. Fidelity Criteria

  22. Fidelity Criteria

  23. Fidelity Criteria

  24. Image Compression Models • The encoder creates a set of symbols (compressed) from the input data. • The data is transmitted over the channel and is fed to decoder. • The decoder reconstructs the output signal from the coded symbols. • The source encoder removes the input redundancies, and the channel encoder increases the noise immunity.

  25. Source Encoder and Decoder

  26. Error-Free Compression 26

  27. Variable-length Coding Methods: Huffman Coding 27

  28. Variable-length Coding Methods: Huffman Coding 28

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  30. Mapping • There is often correlation between adjacent pixels, i.e. the value of the neighbors of an observed pixel can often be predicted from the value of the observed pixel. (Interpixel Redundancy). • Mapping is used to remove Interpixel Redundancy. • Two mapping techniques are: • Run length coding • Difference coding. 30

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  36. LZW Coding (Dictionary based coding) • Dictionary-based coding techniques are based on the idea of incrementally building a dictionary (table) while receiving the data. Unlike VLC techniques, dictionary-based techniques use fixed-length code words to represent variable-length strings of symbols that commonly occur together. • Lempel-Ziv-Welch (LZW) coding assigns fixed length code words to variable length sequences of source symbols. • It also takes care of the interpixel redundancies. • Popular coding scheme used in formats like GIF, TIFF e.t.c 36

  37. LZW Coding (Dictionary based coding) • METHOD • A code book or dictionary containing the source symbols to be coded is constructed. For 8 bit monochrome images, the first 256 words of the dictionary are assigned to the gray values 0,1,2,…,255. As the encoder sequentially examines the image’s pixels, gray level sequences that are not in the dictionary are placed algorithmically determined (e.g., the next unused) locations. If the first two pixels of the image are white, for instance, sequence “255-255” might be assigned to location 256. the next time that two consecutive white pixels are encountered, code word 256, the address of the location containing sequence 255-255, is used to represent them. • A unique feature of LZW coding is that coding dictionary or code book is created while the data are being encoded. 37

  38. Example 38

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  40. Bit-Plane Coding

  41. Binary Image Compression

  42. Binary Image Compression: Constant Area Coding (CAC)

  43. Binary Image Compression: 1-D Run-Length Coding (1D RLC):

  44. Lossy Compression • A lossy compression method is one where compressing data and then decompressing it retrieves data that may well be different from the original, but is close enough to be useful in some way. • Lossy compression is most commonly used to compress multimedia data (audio, video, still images), especially in applications such as streaming media and internet telephony.

  45. JPEG • Lossy Compression Technique based on use of Discrete Cosine Transform (DCT) • A DCT is similar to a Fourier transform in the sense that it produces a kind of spatial frequency spectrum

  46. STEPS IN JPEG COMPRESSION Divide Each plane into 8x8 size blocks. Compute DCT of each block Treat separately DC components of each block. Apply Quantization to discard values Separately encode DC components and transmit data.

  47. JPEG COMPRESSION

  48. JPEG COMPRESSION • Using the DCT, the entries in Y will be organized based on the human visual system. • The most important values to our eyes will be placed in the upper left corner of the matrix. • The least important values will be mostly in the lower right corner of the matrix. Most Important Semi-Important Least Important

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