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MSU CSE 803 Fall 2014

Vectors [and more on masks]. Vector space theory applies directly to several image processing/representation problems. MSU CSE 803 Fall 2014. Image as a sum of “ basic images ”.

abraham-salazar
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MSU CSE 803 Fall 2014

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  1. Vectors [and more on masks] Vector space theory applies directly to several image processing/representation problems MSU CSE 803 Fall 2014

  2. Image as a sum of “basic images” What if every person’s portrait photo could be expressed as a sum of 20 special images?  We would only need 20 numbers to model any photo  sparse rep on our Smart card. MSU CSE 803 Fall 2014

  3. Efaces 100 x 100 images of faces are approximated by a subspace of only 4 100 x 100 “images”, the mean image plus a linear combination of the 3 most important “eigenimages” MSU CSE 803 Fall 2014

  4. The image as an expansion MSU CSE 803 Fall 2014

  5. Different bases, different properties revealed MSU CSE 803 Fall 2014

  6. Fundamental expansion MSU CSE 803 Fall 2014

  7. Basis gives structural parts MSU CSE 803 Fall 2014

  8. Vector space review, part 1 MSU CSE 803 Fall 2014

  9. Vector space review, Part 2 2 MSU CSE 803 Fall 2014

  10. A space of images in a vector space • M x N image of real intensity values has dimension D = M x N • Can concatenate all M rows to interpret an image as a D dimensional 1D vector • The vector space properties apply • The 2D structure of the image is NOT lost MSU CSE 803 Fall 2014

  11. Orthonormal basis vectors help MSU CSE 803 Fall 2014

  12. Represent S = [10, 15, 20] MSU CSE 803 Fall 2014

  13. Projection of vector U onto V MSU CSE 803 Fall 2014

  14. Normalized dot product Can now think about the angle between two signals, two faces, two text documents, … MSU CSE 803 Fall 2014

  15. Every 2x2 neighborhood has some constant, some edge, and some line component Confirm that basis vectors are orthonormal MSU CSE 803 Fall 2014

  16. Roberts basis cont. If a neighborhood N has large dot product with a basis vector (image), then N is similar to that basis image. MSU CSE 803 Fall 2014

  17. Standard 3x3 image basis Structureless and relatively useless! MSU CSE 803 Fall 2014

  18. Frie-Chen basis Confirm that bases vectors are orthonormal MSU CSE 803 Fall 2014

  19. Structure from Frie-Chen expansion Expand N using Frie-Chen basis MSU CSE 803 Fall 2014

  20. Sinusoids provide a good basis MSU CSE 803 Fall 2014

  21. Sinusoids also model well in images MSU CSE 803 Fall 2014

  22. Operations using the Fourier basis MSU CSE 803 Fall 2014

  23. A few properties of 1D sinusoids They are orthogonal Are they orthonormal? MSU CSE 803 Fall 2014

  24. F(x,y) as a sum of sinusoids MSU CSE 803 Fall 2014

  25. Continuous 2D Fourier Transform To compute F(u,v) we do a dot product of our image f(x,y) with a specific sinusoid with frequencies u and v MSU CSE 803 Fall 2014

  26. Power spectrum from FT MSU CSE 803 Fall 2014

  27. Examples from images Done with HIPS in 1997 MSU CSE 803 Fall 2014

  28. Descriptions of former spectra MSU CSE 803 Fall 2014

  29. Discrete Fourier Transform Do N x N dot products and determine where the energy is. High energy in parameters u and v means original image has similarity to those sinusoids. MSU CSE 803 Fall 2014

  30. Bandpass filtering MSU CSE 803 Fall 2014

  31. Convolution of two functions in the spatial domain is equivalent to pointwise multiplication in the frequency domain MSU CSE 803 Fall 2014

  32. LOG or DOG filter Laplacian of Gaussian Approx Difference of Gaussians MSU CSE 803 Fall 2014

  33. LOG filter properties MSU CSE 803 Fall 2014

  34. Mathematical model MSU CSE 803 Fall 2014

  35. 1D model; rotate to create 2D model MSU CSE 803 Fall 2014

  36. 1D Gaussian and 1st derivative MSU CSE 803 Fall 2014

  37. 2nd derivative; then all 3 curves MSU CSE 803 Fall 2014

  38. Laplacian of Gaussian as 3x3 MSU CSE 803 Fall 2014

  39. G(x,y): Mexican hat filter MSU CSE 803 Fall 2014

  40. Convolving LOG with region boundary creates a zero-crossing Mask h(x,y) Input f(x,y) Output f(x,y) * h(x,y) MSU CSE 803 Fall 2014

  41. MSU CSE 803 Fall 2014

  42. LOG relates to animal vision MSU CSE 803 Fall 2014

  43. 1D EX. Artificial Neural Network (ANN) for computing g(x) = f(x) * h(x) level 1 cells feed 3 level 2 cells level 2 cells integrate 3 level 1 input cells using weights [-1,2,-1] MSU CSE 803 Fall 2014

  44. Experience the Mach band effect MSU CSE 803 Fall 2014

  45. Simple model of a neuron MSU CSE 803 Fall 2014

  46. Canny edge detector uses LOG filter MSU CSE 803 Fall 2014

  47. Summary of LOG filter • Convenient filter shape • Boundaries detected as 0-crossings • Psychophysical evidence that animal visual systems might work this way (your testimony) • Physiological evidence that real NNs work as the ANNs MSU CSE 803 Fall 2014

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