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Introduction to Computer and Human Vision Shimon Ullman, Ronen Basri, Michal Irani Assistants: Lena Gorelick Denis Simakov.

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Presentation on theme: "Introduction to Computer and Human Vision Shimon Ullman, Ronen Basri, Michal Irani Assistants: Lena Gorelick Denis Simakov."— Presentation transcript:

1 Introduction to Computer and Human Vision Shimon Ullman, Ronen Basri, Michal Irani Assistants: Lena Gorelick Denis Simakov

2 Misc...  Course website: TBA…  To be added to course mailing-list: send email to Lena  Other recommended courses (for credit): - Basic Topics (I & II) !!! - Advanced Scientific Computation - Numerical Analysis  Vision & Robotics Seminar (not for credit): Thursdays at 12:00-13:00 (Ziskind 1) send email ask to be added to “seminar13” mailing list

3  How is an image formed? (geometry and photometry)  How is it represented?  What kind of operations can we apply to images?  What do images tell us about the world? (analysis & interpretation) Applications: - Manufacturing and inspection; QA - Robot navigation - Autonomous vehicles - Guiding tools for blind - Security and monitoring - Object/face recognition; OCR. - Medical Applications - Visualization; NVS - Visual communication - Digital libraries and video search - Video manipulation and editing

4 Tentative Schedule Lessons 8-9 (Michal): Motion and video analysis Lesson 10 (Ronen): Image Segmentation Lesson 11 (Ronen): Photometry Lesson 12 (Shimon): Object recognition Lesson 13 (Shimon): Human Vision II  3 programming exercises (MATLAB) -- CAN SUBMIT IN PAIRS  3-4 theoretical exercises -- MUST SUBMIT INDIVIDUALLY  EXAM Lesson 1 (Michal): Introduction Lesson 2 (Shimon): Human Vision I Lessons 3-4 (Michal): Basic Image Processing Lessons 5-7 (Ronen): Stereo and Structure from Motion

5 Tentative Schedule Lessons 7-9 (Michal): Motion and video analysis Lesson 10 (Ronen): Image Segmentation Lesson 11 (Ronen): Photometry Lesson 12 (Shimon): Object recognition Lessons 13-14 (Shimon): Human Vision  3 programming exercises (MATLAB) -- CAN SUBMIT IN PAIRS  3-4 theoretical exercises -- MUST SUBMIT INDIVIDUALLY  EXAM Lessons 1-3 (Michal): Basic Image Processing Lessons 4-6 (Ronen): Stereo and Structure from Motion

6 Digital Images WorldCameraDigitizer Digital Image Image Formation: (i) What determines where the image of a 3D point appears on the 2D image? (ii) What determines how bright that image point is? (iii) How is a digital image represented? (iv) Some simple operations on 2D images? today

7 Digital Images WorldCameraDigitizer Digital Image 0 10 10 15 50 70 80 0 0 100 120 125 130 130 0 35 100 150 150 80 50 0 15 70 100 10 20 20 0 15 70 0 0 0 15 5 15 50 120 110 130 110 5 10 20 50 50 20 250 PIXEL Typically: 0 = black 255 = white (picture element)

8 64 60 69 100 149 151 176 182 179 65 62 68 97 145 148 175 183 181 65 66 70 95 142 146 176 185 184 66 66 68 90 135 140 172 184 184 66 64 64 84 129 134 168 181 182 59 63 62 88 130 128 166 185 180 60 62 60 85 127 125 163 183 178 62 62 58 81 122 120 160 181 176 63 64 58 78 118 117 159 180 176

9 210 209 204 202 197 247 143 71 64 80 84 54 54 57 58 206 196 203 197 195 210 207 56 63 58 53 53 61 62 51 201 207 192 201 198 213 156 69 65 57 55 52 53 60 50 216 206 211 193 202 207 208 57 69 60 55 77 49 62 61 221 206 211 194 196 197 220 56 63 60 55 46 97 58 106 209 214 224 199 194 193 204 173 64 60 59 51 62 56 48 204 212 213 208 191 190 191 214 60 62 66 76 51 49 55 214 215 215 207 208 180 172 188 69 72 55 49 56 52 56 209 205 214 205 204 196 187 196 86 62 66 87 57 60 48 208 209 205 203 202 186 174 185 149 71 63 55 55 45 56 207 210 211 199 217 194 183 177 209 90 62 64 52 93 52 208 205 209 209 197 194 183 187 187 239 58 68 61 51 56 204 206 203 209 195 203 188 185 183 221 75 61 58 60 60 200 203 199 236 188 197 183 190 183 196 122 63 58 64 66 205 210 202 203 199 197 196 181 173 186 105 62 57 64 63 x = 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 Grayscale Image y =

10 Three types of images: –Gray-scale images I(x,y)  [0..255] –Binary images I(x,y)  {0, 1} –Color images I R (x,y) I G (x,y) I B (x,y)

11 Color Image

12 Effects of down-sampling (reducing number of pixels) 4 x 4 16 x 16 64 x 64 8 x 8 32 x 32 128 x 128

13 2 gray levels (1 bit/pixel) BINARY IMAGE 4 gray levels (2 bits/pixel) 8 gray levels (3 bits/pixel) 16 gray levels (4 bits/pixel) 256 gray levels (8 bits/pixel) Effects of reducing number of gray levels

14 Occurrence (# of pixels) Gray Level The Image Histogram H(k) = #pixels with gray-level k Normalized histogram: H norm (k)=H(k)/N (N = # pixels in the image) Histogram = The gray-level distribution: Continuous probability density function:

15 The Image Histogram (Cont.) P I (k) k k 1 1 0.5 P I (k) k 0.1

16 P I (k) k 0.5 0.1 P I (k) k 0.1 Histogram Stretching

17 kk kk Histogram Equalization

18 OriginalEqualized Histogram Equalization

19 050100150200250 0 500 1000 1500 2000 2500 3000 050100150200250 0 500 1000 1500 2000 2500 3000 Histogram Equalization OriginalEqualized

20 k AaAa k AbAb Histogram Specification Transforms an image so that its histogram matches that of another image (e.g., for comparing two images of the same scene acquired under different lighting condition)

21 Image Enhancement 1) Gray value (histogram) Domain 2) Spatial Domain 3) Frequency Domain - Histogram stretching - Histogram equalization - Histogram specification - Gamma correction etc... noisy image (salt & pepper noise)

22 Spatial Operations g(x,y) = 1/M  f(n,m) (n,m) in  S S = neighborhood of pixel (x,y) M = number of pixels in neighborhood S e.g., Examples of neighborhoods S: 3 x 3 5 x 5 Replace center pixel with average/median gray level: (averaging mask; weighted mask; median filter…)

23 Salt & Pepper Noise 3 X 3 Average5 X 5 Average 7 X 7 AverageMedian Noise Cleaning

24 Salt & Pepper Noise 3 X 3 Average5 X 5 Average 7 X 7 AverageMedian Noise Cleaning

25 Other spatial filters Are strong brightness variations always noise…?

26 Edge Detection

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31 Edge Types Line Edge gray value x edge gray value x edge Step Edge

32 Vertical edges Horizontal edges Edge Detection Image

33 Original image x derivative Gradient magnitude y derivative

34 Edge Detection Image Also Laplacian; Zero-crossings; Edge sharpening; etc….

35 Image Sharpening Blurry ImageLaplacianSharpened Image

36 Optimal Quantization…?

37 The End...  Exercise#1: Noise Cleaning -- on course website (+ Matlab tutorial) DUE: Nov. 23 (in 3 weeks)  Course mailing list: Send email to  Vision & Robotics Seminar: send email ask to be added to “seminar13” mailing list

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39 Panoramic Mosaic Image Original video clip Generated Mosaic image

40 Original Outliers Original Synthesized Video Removal

41 Image Segmentation

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43 Photometric Stereo

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