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Color Image Processing. 4.6 Color Image Processing. Color simplifies object extraction and identification human vision : thousands of colors vs max-24 gray levels Color Spectrum white light with a prism (1966, Newton). 4.6 Color Image Processing.
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4.6 Color Image Processing • Color • simplifies object extraction and identification • human vision : thousands of colors vs max-24 gray levels • Color Spectrum • white light with a prism (1966, Newton)
4.6 Color Image Processing • RGB : Color Monitor, Color Camera, Color Scanner • CMY : Color Printer, Color Copier • YIQ : Color TV 표준, Y(luminance), I(Inphase), Q(quadrature) • HSI, HSV
4.6 Color Image Processing • RGB Model
4.6 Color Image Processing • CMY Model • Color Printer, Color Copier • RGB dataCMY
4.6 Color Image Processing • RGB to HSI Conversion
4.6 Color Image Processing • HSI to RGB Conversion
Image Retrieval Application • Content-Based Image Retrieval System
Image Retrieval Application • Color Features for Image Indexing • Color Histogram • an estimate of the probability of occurrence of color intensities • 장점 : simple and geometric invariance(translation, rotation, and scaling) • 단점 : lack of spatial information of objects • Dominant Colors • image의 대표 색상 • 잡음에 무관 • Color Monments • moment invariants for color distribution
Image Retrieval Application • Example of Color Histogram in HSI Model • Hue : range [0, 360]- Saturation : range[0, 1] - Intensity : range[0, 1] • Total 36 bin quantization Hue : 6bin Saturation : 2bin Intensity: 3bin
The Course • Books • Computer Vision – Adrian Lowe • Digital Image Processing – Gonzalez, Woods • Image Processing, Analysis and Machine Vision – Milan Sonka, Roger Boyle • Image representation • Image statistics • Histograms (frequency) • Entropy (information) • Filters (low, high, edge, smooth)
Introduction to Digital Image Processing • Human vision - perceive and understand world • Computer vision, Image Understanding / Interpretation, Image processing. • 3D world -> sensors (TV cameras) -> 2D images • Dimension reduction -> loss of information • low level image processing • transform of one image to another • high level image understanding • knowledge based - imitate human cognition • make decisions according to information in image
Acquisition, preprocessing no intelligence Extraction, edge joining Recognition, interpretation intelligent Introduction to Digital Image Processing
Low level digital image processing • Low level computer vision ~ digital image processing • Image Acquisition • image captured by a sensor (TV camera) and digitized • Preprocessing • suppresses noise (image pre-processing) • enhances some object features - relevant to understanding the image • edge extraction, smoothing, thresholding etc. • Image segmentation • separate objects from the image background • colour segmentation, region growing, edge linking etc • Object description and classification • after segmentation
Signals and Functions • What is an image • Signal = function (variable with physical meaning) • one-dimensional (e.g. dependent on time) • two-dimensional (e.g. images dependent on two co-ordinates in a plane) • three-dimensional (e.g. describing an object in space) • higher-dimensional • Scalar functions • sufficient to describe a monochromatic image - intensity images • Vector functions • represent color images - three component colors
Image Functions • Image - continuous function of a number of variables • Co-ordinates x, y in a spatial plane • for image sequences - variable (time) t • Image function value = brightness at image points • other physical quantities • temperature, pressure distribution, distance from the observer • Image on the human eye retina / TV camera sensor - intrinsically 2D • 2D image using brightness points = intensity image • Mapping 3D real world -> 2D image • 2D intensity image = perspective projection of the 3D scene • information lost - transformation is not one-to-one • geometric problem - information recovery • understanding brightness info
Image Acquisition & Manipulation • Analogue camera • frame grabber • video capture card • Digital camera / video recorder • Capture rate 30 frames / second • HVS persistence of vision • Computer, digitised image, software (usually c) • f(x,y) #define M 128 #define N 128 unsigned char f[N][M] • 2D array of size N*M • Each element contains an intensity value
Image definition • Image definition: • A 2D function obtained by sensing a scene • F(x,y), F(x1,x2), F(x) • F - intensity, grey level • x,y - spatial co-ordinates • No. of grey levels, L = 2B • B = no. of bits
Brightness and 2D images • Brightness dependent several factors • object surface reflectance properties • surface material, microstructure and marking • illumination properties • object surface orientation with respect to a viewer and light source • Some Scientific / technical disciplines work with 2D images directly • image of flat specimen viewed by a microscope with transparent illumination • character drawn on a sheet of paper • image of a fingerprint
Monochromatic images • Image processing - static images - time t is constant • Monochromatic static image - continuous image function f(x,y) • arguments - two co-ordinates (x,y) • Digital image functions - represented by matrices • co-ordinates = integer numbers • Cartesian (horizontal x axis, vertical y axis) • OR (row, column) matrices • Monochromatic image function range • lowest value - black • highest value - white • Limited brightness values = gray levels
Chromatic images • Colour • Represented by vector not scalar • Red, Green, Blue (RGB) • Hue, Saturation, Value (HSV) • luminance, chrominance (Yuv , Luv) S=0 Green Hue degrees: Red, 0 deg Green 120 deg Blue 240 deg Red Green V=0
Image quality • Quality of digital image proportional to: • spatial resolution • proximity of image samples in image plane • spectral resolution • bandwidth of light frequencies captured by sensor • radiometric resolution • number of distinguishable gray levels • time resolution • interval between time samples at which images captured
Image summary • F(xi,yj) • i = 0 --> N-1 • j = 0 --> M-1 • N*M = spatial resolution, size of image • L = intensity levels, grey levels • B = no. of bits
Digital Image Storage • Stored in two parts • header • width, height … cookie. • Cookie is an indicator of what type of image file • data • uncompressed, compressed, ascii, binary. • File types • JPEG, BMP, PPM.
PPM, Portable Pixel Map • Cookie • Px • Where x is: • 1 - (ascii) binary image (black & white, 0 & 1) • 2 - (ascii) grey-scale image (monochromic) • 3 - (ascii) colour (RGB) • 4 - (binary) binary image • 5 - (binary) grey-scale image (monochromatic) • 6 - (binary) colour (RGB)
PPM example • PPM colour file RGB P3 # feep.ppm 4 4 15 0 0 0 0 0 0 0 0 0 15 0 15 0 0 0 0 15 7 0 0 0 0 0 0 0 0 0 0 0 0 0 15 7 0 0 0 15 0 15 0 0 0 0 0 0 0 0 0
Installing CVIPtools • Download the appropriate installation from http://www.ee.siue.edu/CVIPtools/ • Double-click on binWin32.tar.gz • Agree to the WinZip conditions. • Answer the “Should WinZip decompress it to a temporary folder and open it?” YES • You will see the WinZip window with over 1100 files, find the file install.exe and double-click on it • You will see an “Install” window with the statement “WinZip will extract all files to a temporary folder and run the install.exe program” Press OK
Installing CVIPtools • WinZip will extract the files to c:\windows\TEMP\install • You will see the CVIPtools Installation window with the statement “Press OK to proceed with installation, Press Cancel to abort installation” Press OK • You will see the Select source drive directory, which should be C:\WINDOWS\TEMP\install. Press OK • You will see the Select destination drive and directory. Press the “..” until you see the directory C:\CVIPtools, then press OK • You will see the Select installation type and options window. Select Binary installation and press OK
Installing CVIPtools • You will see a Copying files message. Wait for the program to finish. You will see the CVIPtools Installation complete message. Press OK. • You will see a Install window with the question. When install.exe completes press the OK button to return to WinZip. Press OK. • Exit from WinZip • Go to C:\CVIPtools\bin • Make a shortcut to CVIPtools.bat • To run CVIPtools double-click on the shortcut.
Image presentation (1) 1.1 Image capture, representation, and storage: digital image, DPI, pixel... Example:Various quantizing level: (a) 6 bits; (b) 4 bits; (c) 2 bits; (d) 1 bit.
Image presentation (2) • 1.2 Color representation: Color systems: RGB, CMY/CMYK, HSI, YCbCr
Sources • Department of Pattern Recognition and Knowledge Engineering • Institute of Information Technology • Hanoi, Vietnam • Represented by LUONG CHI MAI • lcmai@ioit.ncst.ac.vnEinführung in die erweiterte Realität Virtual Reality Modeling Language (VRML) Prof. G. Klinker, Prof. B. Brügge 19. Mai 2000 • Schenney UC Berkeley
SUPPLEMENTAL READING • Jensen. 1996. Introductory Digital Image Processing. (Upper Saddle River, NJ: Prentice Hall). Ed. 2. Ch. 2 (60-61), Ch. 3, and Ch. 4
Sources • Maja Mataric • Dodds, Harvey Mudd College • Damien Blond • Alim Fazal • Tory Richard • Jim Gast • Bryan S. Morse • Gerald McGrath • Vanessa S. Blake • Many sources of slides from Internet http://www.cheng.cam.ac.uk/seminars/imagepro/
Sources • 533 Text book • http://sern.ucalgary.ca/courses/CPSC/533/W99/ • presentations/L2_24A_Lee_Wang/ • http://sern.ucalgary.ca/courses/CPSC/533/W99/ • presentations/L1_24A_Kaasten_Steller_Hoang/main.htm • http://sern.ucalgary.ca/courses/CPSC/533/W99/ • presentations/L1_24_Schebywolok/index.html • http://sern.ucalgary.ca/courses/CPSC/533/W99/ • presentations/L2_24B_Doering_Grenier/ • http://www.geocities.com/SoHo/Museum/3828/ • optical.html • http://members.spree.com/funNgames/katbug/
Sources • Bryan S. Morse • Prof. Paolo Dario • Cecilia Laschi • Many WWW sources • Anup Basu, Ph.D. Professor, Dept of Computing Sc. University of Alberta • Professor Kim, KAIST • Computer science, University of Massachusetts, Web Site: www-edlab.cs.umass/cs570
Companies in Canada • BIOLOGICAL • Morphometrix (Toronto): automated pap smear testing • DEFENSE/INTELLIGENCE • SPAR Aerospace (Toronto, Edmonton): detection of targets in radar clutter • DOCUMENT PROCESSING • NCR: check processing; character recognition • FACTORY AUTOMATION • IPS Automation (Markham): automated bottle thread and CRT inspection • IO Industries (London): image acquisition • MEDICAL • Forward Imaging (London) • EVS (London) • Cedara Software (Mississauga) • Mitra (Waterloo) • Dicomit (Markham) • ...
Summary Should know following terms: • digital image (pixel, gray level) • colormap • digitization • continuous-tone image • sampling • quantization • dynamic range • spatial resolution • pixelation • brightness resolution • posterization & brightness contouring • digital image processing • digital image analysis
Human Vision and Machine Vision • Digital Image • Image Formation • Image Processing Operations for Early Vision • Applications of Early Image Processing • Extracting 3D Information using Vision • Using Vision for Manipulation and Navigation • Object Representation and Recognition • Perception Outline • Light and Optics • Pinhole camera model • Perspective projection • Thin lens model • Fundamental equation • Distortion: spherical & chromatic aberration, radial distortion • Reflection and Illumination: color, lambertian and specular surfaces, Phong, BDRF • Sensing Light • Conversion to Digital Images • Sampling Theorem • Other Sensors: frequency, type, …. Start from
Computer Scanner Photo card reader Examples of simple image processing
What do I do with it? • Option 1 • Open it in PhotoEditor • Print it out to Deskjet printer • Laminate it • Stick it on your poster
What do I do with it? • Option 2 • Open it in PhotoEditor • Crop and resize to the size it will appear in the final product • Import image into Word • Print report from Word
What do I do with it? - Option 3 • Open it in PhotoEditor • Crop and resize to the size it will appear in the final product • Import image into PowerPoint • Use PowerPoint for presentation or • Take PowerPoint file to P&IS for printing as a poster (this costs money)
Don't copy and paste images into Word and PowerPoint Always use Insert Picture From file
Don’t just insert it into your document and resize by dragging its sizing handles If you make it look smaller, it’s still same filesize