Geometric and Point Transforms

Geometric and Point Transforms

Copyright GA Tagliarini, PhD
Standard Angles Rotation or reflection through standard angles such as 90°, 180°, or 270° can be done most conveniently via direct index. Intermediate angle rotations employ matrix manipulations of the indices 11/30/2018 Copyright GA Tagliarini, PhD

Rotation By Matrix Multiplication
11/30/2018 Copyright GA Tagliarini, PhD

Rotating The Standard Basis

Graphically Portraying The Standard Basis Rotation
<0, 1> <-sin(θ), cos(θ)> -sin(θ) <cos(θ), sin(θ)> cos(θ) θ sin(θ) θ <1, 0> cos(θ) 11/30/2018 Copyright GA Tagliarini, PhD

Rotating An Arbitrary Point <x, y>

Geometrically Interpreting Rotation
<xcos(θ)-ysin(θ), xsin(θ)+ycos(θ)> = <rcos(α+θ), rsin(α+θ)> Why?? <0, 1> r y or y<0, 1> <x, y> = <r cos(α), r sin(α)> r θ α x or x<1, 0> <1, 0> 11/30/2018 Copyright GA Tagliarini, PhD

Observations About Rotation
Depending upon the rotation angle and image dimension, special processing may be required for some pixels Matrix multiplication applied to pixel indices provides access to pixel values for the destination image Working from the source to the destination may omit pixels 11/30/2018 Copyright GA Tagliarini, PhD

Spatial Filtering Common types of filtering Smoothing: averaging may be done Over multiple images to de-noise the source To reduce noise or soften the appearance in a single image Speckle reducing Edge enhancing Often implemented by point operations using neighborhood data and a filter Filters are commonly represented with rectangular arrays of numbers The numeric values are the coefficients of the filter The arrays may be referred to as masks, kernels, templates, windows 11/30/2018 Copyright GA Tagliarini, PhD

Smoothing Filter: Averaging In An Image

Geometrical Interpretation
11/30/2018 Geometrical Interpretation s a b c d e f g h i 1/9 r c 11/30/2018 Copyright GA Tagliarini, PhD Copyright GA Tagliarini, PhD

Averaging Observations
Average filtering will reduce the clarity of sharp edges. (Why?) The form of the filter is typically adapted at the boundaries of the image to accommodate computation. This 3x3 filter becomes: 2x2 at the image corners (with coefficients = ¼) 2x3 along the top and bottom, and 3x2 along the left and right sides (with coefficients = 1/6) 11/30/2018 Copyright GA Tagliarini, PhD

Averaging Observations (continued)
Averaging (and other) filters are commonly square with odd side length (so that they possess a center weight). The center weight may be zero. The weights are not required all to have the same value. The sum of the weights will be 1. Not all filters will be symmetric. 11/30/2018 Copyright GA Tagliarini, PhD

Example Averaging Filters
Some other averaging filters: 1/8 1 = 1 2 3 7 11 17 1/16 2/16 4/16 1 2 4 = 11/30/2018 Copyright GA Tagliarini, PhD

Speckle Reduction By Median Filtering
Median filters are another type of spatial filter. Suppose a neighborhood of odd side length, sl = 2m+1 for pixel (r, c) in an image s, denoted N(s, r, c, sl). To apply a median filter: Find the median intensity, mi, of the pixels in N(s, r, c, m); i.e., mi = median( N(s, r, c, sl)) Set d(r, c) = mi 11/30/2018 Copyright GA Tagliarini, PhD

Median Filtering The median can be found by sorting the pixel intensities in N(s, r, c, sl) It is NOT necessary to sort the list of pixel intensities completely. (Why?) Exercises Implement monochrome and multi-spectral median filters. What happens when a median filter is applied recursively? How does this differ from the result of recursively applying a smoothing filter? 11/30/2018 Copyright GA Tagliarini, PhD

Contrast Enhancement Polynomial or root transformations Log transformations Histogram equalization 11/30/2018 Copyright GA Tagliarini, PhD

Polynomial And Root Transforms

Log Transforms 11/30/2018 Copyright GA Tagliarini, PhD

Key Insight: Changing Contrast
f(x) When f’>1, a unit change in x results more than a unit change in y When f’<1, a unit change in x results less than a unit change in y When f’≈1, a unit change in x results approximately a unit change in y y f’<1 f’≈1 x f’>1 11/30/2018 Copyright GA Tagliarini, PhD

An Typical Image Histogram

Overlaying The Histograms

Cumulative Histogram Similar to a probability density function Increases contrast where the most frequently occurring pixel intensities lie Used for monochrome images but separate application to RGB color planes leads to surreal images 11/30/2018 Copyright GA Tagliarini, PhD

Sharpening Unlike smoothing filters, the goal is to enhance detail that has been blurred Averaging filters typically use a scaled weighted sum (an integration) Sharpening filters commonly employ differences (derivatives) 11/30/2018 Copyright GA Tagliarini, PhD

Derivatives Recall that the derivative of a function f at a point a may be defined as when the limit exists. 11/30/2018 Copyright GA Tagliarini, PhD

Graphically a x f(x)-f(a) x-a 11/30/2018 Copyright GA Tagliarini, PhD

With Digital Samples The closest approximation is when x=a+1 So x-a=1 Hence f(a+1)-f(a) is an estimate of f’(a) a x f(x)-f(a) x-a 11/30/2018 Copyright GA Tagliarini, PhD

One Dimensional Derivative
… f(x) f(x+1) 11/30/2018 Copyright GA Tagliarini, PhD

One Dimensional Second Derivative
… f(x-1) f(x) f(x+1) 11/30/2018 Copyright GA Tagliarini, PhD

Laplacian 1 -4 Which gives rise to the mask 11/30/2018
1 -4 Which gives rise to the mask 11/30/2018 Copyright GA Tagliarini, PhD

Enhancement Using The Laplacian

A One-Dimensional Example

Example Detail f 50 45 40 35 30 25 20 60 100 140 180 220 120 200 f' -5 -100 -180 f'' 5 -140 -360 f# 15 260 -80 380 -160 scaled f# [20, 220] 98 94 92 90 89 87 85 116 131 146 161 176 clipped f# clipped f# 255 11/30/2018 Copyright GA Tagliarini, PhD

Alternative Laplacian Masks
Implementing the computational simplification use: To employ diagonal derivatives in addition to x-y use -1 5 -1 9 11/30/2018 Copyright GA Tagliarini, PhD

Example With f, f’, f’’, and Sharpened f

Example With Sharpening

Gradient Operators For Enhancement
Robert’s cross-gradient (2x2) Prewitt’s gradient (3x3) Sobel operator (3x3) These use the magnitude of a gradient estimate to create image enhancements 11/30/2018 Copyright GA Tagliarini, PhD

Creating And Using Gradient Estimates
Often, the sum of the absolute values of Gx and Gy are used Computationally, |Gx| and |Gy| take much less time to compute than squaring and finding a square root of a sum. Hence, the gradient magnitude may be estimated by 11/30/2018 Copyright GA Tagliarini, PhD

Using Gradient Operators
Estimate the gradient magnitudes and create a gradient magnitude map. Often the gradient map is half-toned using an anecdotally determined threshold. The gradient map may be used directly to find edges. The half-toned map (or its negative) can be “OR-ed” with the original for interpretation. 11/30/2018 Copyright GA Tagliarini, PhD

Robert’s Cross-Gradient Operators
Robert’s cross-gradient is estimated using |grad(f)| = |z9-z5|+|z8-z6| Using the masks below to estimate derivatives: z1 z2 z3 z4 z5 z6 z7 z8 z9 -1 1 -1 1 11/30/2018 Copyright GA Tagliarini, PhD

Prewitt’s Gradient Map

Sobel Masks Sobel’s gradient is estimated using |grad(f)| = |z3-z1|+|z6-z4|+|z9-z7| Using the masks below to estimate derivatives: z1 z2 z3 z4 z5 z6 z7 z8 z9 -1 1 -2 2 -1 -2 1 2 11/30/2018 Copyright GA Tagliarini, PhD

Using Sobel’s Gradient

Using Sobel’s Gradient With Wavelet

Geometric and Point Transforms

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