Post on 09-Feb-2016
description
CIS 601
Image Fundamentals
Dr. Rolf Lakaemper
Fundamentals
Parts of these slides base on the textbook
Digital Image Processingby Gonzales/Woods
Chapters 1 / 2
Fundamentals
These slides show
basic concepts about digital images
Fundamentals
Let’s have a look at the human eye
Fundamentals
Fundamentals
We are mostly interested in the retina:
• consists of cones and rods• Cones• color receptors• About 7 million, primarily in the retina’s
central portion • for image details
• Rods• Sensitive to illumination, not involved in
color vision• About 130 million, all over the retina• General, overall view
Fundamentals
The human eye
• Is able to perceive electromagnetic waves in a certain spectrum
• Is able to distinguish between wavelengths in this spectrum (colors)
• Has a higher density of receptors in the center
• Maps our 3D reality to a 2 dimensional image !
Fundamentals
…or more precise:
maps our continous (?) reality to a (spatially) DISCRETE 2D image
Fundamentals
Some topics we have to deal with:
• Sharpness• Brightness
• Processing of perceived visual information
Fundamentals
Sharpness
The eye is able to deal with sharpness in different distances
Fundamentals
Brightness
The eye is able to adapt to different ranges of brightness
Fundamentals
Processing of perceived information: optical illusions
Fundamentals
optical illusions:
Digital Image Processing does NOT (primarily) deal with cognitive
aspects of the perceived image !
Fundamentals
What is an image ?
Fundamentals
The retinal model is mathematically hard to handle (e.g. neighborhood ?)
Fundamentals
Easier: 2D array of cells, modelling the cones/rods
Each cell contains a numerical value (e.g. between 0-255)
Fundamentals
• The position of each cell defines the position of the receptor
• The numerical value of the cell represents the illumination received by the receptor
5 7 1 0 12 4 ………
Fundamentals
• With this model, we can create GRAYVALUE images
• Value = 0: BLACK (no illumination / energy)
• Value = 255: White (max. illumination / energy)
Fundamentals
A 2D grayvalue - image is a 2D -> 1D function,
v = f(x,y)
Fundamentals
As we have a function, we can apply operators to this function, e.g.
H(f(x,y)) = f(x,y) / 2
Operator Image (= function !)
Fundamentals
H(f(x,y)) = f(x,y) / 2
6 8 2 0
12 200 20 10
3 4 1 0
6 100 10 5
Fundamentals
Remember: the value of the cells is the illumination (or brightness)
6 8 2 0
12 200 20 10
3 4 1 0
6 100 10 5
Fundamentals
The mandatory steps:
Image Acquisition and Representation
Fundamentals
Acquisition
Fundamentals
Acquisition
Fundamentals
Typical sensor for images:
CCD Array (Charge Couple Devices)
• Use in digital cameras• Typical resolution 1024 x 768
(webcam)
Fundamentals
CCD
Fundamentals
CCD
Fundamentals
CCD (3.2 million pixels)
Fundamentals
Representation
The Braun Tube
Fundamentals
Representation
Black/White and Color
Fundamentals
Color Representation: Red / Green / Blue
Model forColor-tube
Note: RGB is not the ONLY color-model, in fact its use is quiet restricted. More about that later.
Fundamentals
Color images can be represented by3D Arrays (e.g. 320 x 240 x 3)
Fundamentals
But for the time being we’ll handle
2D grayvalue images
Fundamentals
Digital vs. Analogue Images
Analogue:Function v = f(x,y): v,x,y are REAL
Digital:Function v = f(x,y): v,x,y are INTEGER
Fundamentals
Stepping down from REALity to INTEGER coordinates x,y: Sampling
Fundamentals
Stepping down from REALity to INTEGER grayvalues v : Quantization
Fundamentals
Samplingand
Quantization
Fundamentals
MATLAB demonstrations of sampling and quantization effects