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Digital Image Processing Week VIII

Color Image Processing. Digital Image Processing Week VIII. Thurdsak LEAUHATONG. Spectrum of White Light . 1666 Sir Isaac Newton, 24 year old, discovered white light spectrum. Electromagnetic Spectrum . Visible light wavelength: from around 400 to 700 nm.

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Digital Image Processing Week VIII

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  1. Color Image Processing Digital Image Processing Week VIII Thurdsak LEAUHATONG

  2. Spectrum of White Light 1666 Sir Isaac Newton, 24 year old, discovered white light spectrum.

  3. Electromagnetic Spectrum Visible light wavelength: from around 400 to 700 nm 1. For an achromatic (monochrome) light source, there is only 1 attribute to describe the quality:intensity 2. For a chromatic light source, there are 3 attributes to describe the quality: Radiance = total amount of energy flow from a light source (Watts) Luminance = amount of energy received by an observer (lumens) Brightness= intensity

  4. Sensitivity of Cones in the Human Eye 6-7 millions cones in a human eye - 65% sensitive to Red light - 33% sensitive to Green light - 2 % sensitive to Blue light Primary colors: Defined CIE in 1931 Red = 700 nm Green = 546.1nm Blue = 435.8 nm CIE = Commission Internationale de l’Eclairage (The International Commission on Illumination)

  5. Primary and Secondary Colors Primary color Secondary colors Primary color Primary color

  6. Primary and Secondary Colors (cont.) Additive primary colors: RGB use in the case of light sources such as color monitors RGB add together to get white Subtractive primary colors: CMY use in the case of pigments in printing devices White subtracted by CMY to get Black

  7. Color Characterization Hue: dominant color corresponding to a dominant wavelength of mixture light wave Saturation: Relative purity or amount of white light mixed with a hue (inversely proportional to amount of white light added) Brightness: Intensity Hue Saturation Chromaticity amount of red (X),green (Y) and blue (Z) to form any particular color is called tristimulus.

  8. CIE Chromaticity Diagram Trichromatic coefficients: y Points on the boundary are fully saturated colors x

  9. Color Gamut of Color Monitors and Printing Devices Color Monitors Printing devices

  10. RGB Color Model Purpose of color models: to facilitate the specification of colors in some standard • RGB color models: • based on cartesian • coordinate system

  11. RGB Color Cube R = 8 bits G = 8 bits B = 8 bits Color depth 24 bits = 16777216 colors Hidden faces of the cube

  12. RGB Color Model (cont.) Red fixed at 127

  13. RGB Safe-color Cube The RGB Cube is divided into 6 intervals on each axis to achieve the total 63 = 216 common colors. However, for 8 bit color representation, there are the total 256 colors. Therefore, the remaining 40 colors are left to OS.

  14. CMY and CMYK Color Models C = Cyan M = Magenta Y = Yellow K = Black

  15. HSI Color Model RGB, CMY models are not good for human interpreting HSI Color model: Hue: Dominant color Saturation: Relative purity (inversely proportional to amount of white light added) Intensity: Brightness Color carrying information

  16. Relationship Between RGB and HSI Color Models RGB HSI

  17. Hue and Saturation on Color Planes 1. A dot is the plane is an arbitrary color 2. Hue is an angle from a red axis. 3. Saturation is a distance to the point.

  18. HSI Color Model (cont.) Intensity is given by a position on the vertical axis.

  19. HSI Color Model Intensity is given by a position on the vertical axis.

  20. Example: HSI Components of RGB Cube RGB Cube Hue Saturation Intensity

  21. Converting Colors from RGB to HSI

  22. Converting Colors from HSI to RGB RG sector: GB sector: BR sector:

  23. Example: HSI Components of RGB Colors RGB Image Hue Saturation Intensity

  24. Color Image Processing There are 2 types of color image processes 1. Pseudocolor image process: Assigning colors to gray values based on a specific criterion. Gray scale images to be processed may be a single image or multiple images such as multispectral images 2. Full color image process: The process to manipulate real color images such as color photographs.

  25. Pseudocolor Image Processing Pseudo color = false color : In some case there is no “color” concept for a gray scale image but we can assign “false” colors to an image. Why we need to assign colors to gray scale image? Answer: Human can distinguish different colors better than different shades of gray.

  26. Intensity Slicing or Density Slicing Formula: C1 = Color No. 1 C2 = Color No. 2 Color T C2 C1 T 0 L-1 Intensity A gray scale image viewed as a 3D surface.

  27. Intensity Slicing Example An X-ray image of a weld with cracks After assigning a yellow color to pixels with value 255 and a blue color to all other pixels.

  28. Multi Level Intensity Slicing Ck = Color No. k lk = Threshold level k Color Ck Ck-1 C3 C2 C1 l1 l2 l3 lk-1 lk 0 L-1 Intensity

  29. Multi Level Intensity Slicing Example Ck = Color No. k lk = Threshold level k An X-ray image of the Picker Thyroid Phantom. After density slicing into 8 colors

  30. Color Coding Example A unique color is assigned to each intensity value. Gray-scale image of average monthly rainfall. Color map Color coded image South America region

  31. Gray Level to Color Transformation Assigning colors to gray levels based on specific mapping functions Red component Gray scale image Green component Blue component

  32. Gray Level to Color Transformation Example An X-ray image of a garment bag with a simulated explosive device An X-ray image of a garment bag Transformations Color coded images

  33. Gray Level to Color Transformation Example An X-ray image of a garment bag with a simulated explosive device An X-ray image of a garment bag Transformations Color coded images

  34. Pseudocolor Coding Used in the case where there are many monochrome images such as multispectral satellite images.

  35. Pseudocolor Coding Example Visible blue • = 0.45-0.52 mm Max water penetration Visible green • = 0.52-0.60 mm Measuring plant Color composite images 1 2 Red = Green = Blue = Red = Green = Blue = 1 1 3 4 2 2 3 4 Visible red • = 0.63-0.69 mm Plant discrimination Near infrared • = 0.76-0.90 mm Biomass and shoreline mapping Washington D.C. area

  36. Pseudocolor Coding Example Psuedocolor rendition of Jupiter moon Io Yellow areas = older sulfur deposits. Red areas = material ejected from active volcanoes. A close-up

  37. Basics of Full-Color Image Processing Two Methods: 1. Per-color-component processing: process each component separately. 2. Vector processing: treat each pixel as a vector to be processed. Example of per-color-component processing: smoothing an image By smoothing each RGB component separately.

  38. Example: Full-Color Image and Variouis Color Space Components Color image CMYK components RGB components HSI components

  39. Color Transformation Use to transform colors to colors. Formulation: f(x,y) = input color image, g(x,y) = output color image T = operation on fover a spatial neighborhood of (x,y) When only data at one pixel is used in the transformation, we can express the transformation as: i= 1, 2, …, n For RGB images, n = 3 Where ri = color component of f(x,y) si = color component of g(x,y)

  40. Example: Color Transformation Formula for RGB: k = 0.7 Formula for HSI: Formula for CMY: I H,S These 3 transformations give the same results.

  41. Color Complements Color complement replaces each color with its opposite color in the color circle of the Hue component. This operation is analogous to image negative in a gray scale image. Color circle

  42. Color Complement Transformation Example

  43. Color Slicing Transformation We can perform “slicing” in color space: if the color of each pixel is far from a desired color more than threshold distance, we set that color to some specific color such as gray, otherwise we keep the original color unchanged. Set to gray Keep the original color i= 1, 2, …, n or Set to gray Keep the original color i= 1, 2, …, n

  44. Color Slicing Transformation Example After color slicing Original image

  45. Tonal Correction Examples In these examples, only brightness and contrast are adjusted while keeping color unchanged. This can be done by using the same transformation for all RGB components. Contrast enhancement Power law transformations

  46. Color Balancing Correction Examples Color imbalance: primary color components in white area are not balance. We can measure these components by using a color spectrometer. Color balancing can be performed by adjusting color components separately as seen in this slide.

  47. Histogram Equalization of a Full-Color Image • Histogram equalization of a color image can be performed by • adjusting color intensity uniformly while leaving color unchanged. • The HSI model is suitable for histogram equalization where only • Intensity (I) component is equalized. where r and s are intensity components of input and output color image.

  48. Histogram Equalization of a Full-Color Image Original image After histogram equalization After increasing saturation component

  49. Color Image Smoothing Two methods: • Per-color-plane method: for RGB, CMY color models • Smooth each color plane using moving averaging and • the combine back to RGB • Smooth only Intensity component of a HSI image while leaving • H and S unmodified.

  50. Color Image Smoothing Example (cont.) Red Color image Green Blue

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