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Image recognition using analysis of the frequency domain features

Image recognition using analysis of the frequency domain features. Image Recognition. Image recognition problem is a problem of recognition of some certain objects that are located in an image. Image Recognition.

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Image recognition using analysis of the frequency domain features

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  1. Image recognition using analysis of the frequency domain features

  2. Image Recognition • Image recognition problem is a problem of recognition of some certain objects that are located in an image.

  3. Image Recognition • To solve any pattern recognition/classification problem, it is necessary to find a relevant set of those features that can exhaustively describe an object to be recognized. • We never will confuse recognizing where is a tiger and where is a rabbit, but how an automatic tool can decide who is who?

  4. Image Recognition: Features Selection • Can you propose a set of features using which we can definitely distinguish a tiger from a rabbit?

  5. Image Recognition: Features Selection • It is often difficult to find a proper set of those features that would be really exhaustive and would not be redundant (redundancy complicates both processes of learning and recognition). • Another problem is a formal representation of the selected features.

  6. Image Recognition: Features Selection • PCA (Principal Component Analysis) is a method, which is often used for obtaining the objective features. • PCA is based on the Karhunen-Loeve transformation of a signal (a transformation by the eigenvectors of the covariance matrix of the ensemble of signals), which is computationally very costly.

  7. Image Recognition: Features Selection • The idea behind PCA is to find a small amount of those eigenvectors (and spectral coefficients, respectively) that make a major contribution to the formation of a signal • The question: is it possible to find another approach to obtaining the objective features?

  8. Image Recognition: Features Selection • Oppenheim, A.V.; Lim, J.S., The importance of phase in signals, IEEE Proceedings, v. 69, No 5, 1981,pp.:  529- 541 • In this paper, it was shown that phase in the Fourier spectrum of an image is much more informative than magnitude: phase contains the information about all shapes, edges, orientation of all objects, etc.

  9. Image Recognition: Features Selection • Thus the Fourier Phase Spectrum can be a very good source of the objective features that describe all objects located in images. • The Power Spectrum (magnitude) describes global image properties (blur, noise, cleanness, contrast, brightness, etc.).

  10. Phase and Magnitude Phase contains the information about an object presented by a signal (a) (b) Phase(a) & Magnitude (b) Phase (b) & Magnitude (a)

  11. Phase and Magnitude Magnitude contains the information about the signal’s properties (a) (b) Phase(a) & Magnitude(b) Phase (b) & Magnitude (a)

  12. Phase and Magnitude • Blur with a symmetric point-spread function practically does not affect the phase, while the magnitude may be distorted significantly. • This property may be use for recognition of blurred images using a phase spectrum as a feature space.

  13. Image Recognition: Features Selection • Since the Fourier Transform is computationally much simpler and more efficient than the Karhunen-Loeve transform (because of the existence of a number of Fast Fourier Transform algorithms), the use of the Fourier phases as the features for object recognition is very attractive.

  14. Image Recognition: Decision Rule and Classifier • The next question is: is it possible to formulate (and formalize!) the decision rule, using which we can classify or recognize our objects basing on the selected features? • Can you propose the rule using which we can definitely decide is it a tiger or a rabbit?

  15. Image Recognition: Decision Rule and Classifier • Once we know our decision rule, it is not difficult to develop a classifier, which will perform classification/recognition using the selected features and the decision rule. • However, if the decision rule can not be formulated and formalized, we should use a classifier, which can develop the rule from the learning process

  16. Image Recognition: Decision Rule and Classifier • In the most of recognition/classification problems, the formalization of the decision rule is very complicated or impossible at all. • A neural network is a tool, which can accumulate knowledge from the learning process. • After the learning process, a neural network is able to approximate a function, which is supposed to be our decision rule

  17. Why neural network? - unknown multi-factor decision rule Learning process using a representative learning set - a set of weighting vectors is the result of the learning process - a partially defined function, which is an approximation of the decision rule function

  18. Image Recognition: Approach • We will use the low frequency Fourier phases as the features. They contain the most important information about those objects that we want to recognize • We will use a neural network as a classifier

  19. Features Selection Features are selected from the low frequency part of the Fourier phasespectrum

  20. Example: Classification of Gene Expression Patterns

  21. Gene expression patterns • We have studied spatio-temporal expression patterns of genes controlling segmentation in the embryo of fruit fly Drosophila. • A problem is to perform temporal classification of the gene expression patterns taken form the confocal electronic microscope (8 temporal classes are considered)

  22. Image of gene expression data in Drosophila embryoobtained by confocalscanning microscopy

  23. Class 1 Class 2 Class 3 Class 4 Class 5 Class 6 Class 7 Class 8 A problem of the classification Representatives of 8 temporal classes:

  24. Phases as the features Class 1 Class 8 Phase Cl.1+ Amplitude Cl.8 Phase Cl.8 + Amplitude Cl.1

  25. Learning process • From 28 up to 32 images from each class a priori correctly classified as “representative” from biological view were used for the learning • From 60 inputs up to 144 inputs (from 5 to 8 low frequency coefficients) have been used as the features

  26. The Classification Results

  27. Problems that we will consider • Textures classification (automatic classification of different Gaussian and uniform textures) • Blurred images recognition

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