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DIFFERENT TYPES OF CORONAS AND MACHINE LEARNING
CLASSIFICATION OF DIFFERENT TYPES OF CORONAS USINGÂ PARAMETRIZATION OF IMAGES AND MACHINE LEARNING
Igor Kononenko, Matjaz Bevk, Sasa Sadikov, Luka Sajn University of Ljubljana, Faculty of Computer and Information Science, Ljubljana, Slovenia Abstract We describe the development of computer classifiers for various types of coronas. In particular, we were interested to develop an algorithm for detection of coronas of people in altered states of consciousness (two-classes problem). Such coronas are known to have rings (double coronas), special branch-like structure of streamers and/or curious spots. Besides detecting altered states of consciousness we were interested also to classify various types of coronas (six-classes problem). We used several approaches to parametrization of images: statistical approach, principal component analysis, association rules and GDV software approach extended with several additional parameters. For the development of the classifiers we used various machine learning algorithms: learning of decision trees, naĂŻve Bayesian classifier, K-nearest neighbors classifier, Support vector machine, neural networks, and Kernel Density classifier. We compared results of computer algorithms with the human expertâs accuracy (about 77% for the two-classes problem and about 60% for the six-classes problem). Results show that computer algorithms can achieve the same or even better accuracy than that of human experts (best results were up to 85% for the two-classes problem and up to 65% for the six-classes problem). 1. Introduction Recently developed technology by dr. Korotkov (1998) from Technical University in St.Petersburg, based on the Kirlian effect, for recording the human bio-electromagnetic field (aura) using the Gas Discharge Visualization (GDV) technique provides potentially useful information about the biophysical and/or psychical state of the recorded person. In order to make the unbiased decisions about the state of the person we want to be able to develop the computer algorithm for extracting information/describing/classifying/making decisions about the state of the person from the recorded coronas of fingertips. The aim of our study is to differentiate 6 types of coronas, 3 types in normal state of consciousness: Ia, Ib, Ic (pictures were recorded with single GDV camera in Ljubljana, all with the same settings of parameters, classification into 3 types was done manually): ï¶Â Ia â harmonious energy state (120 coronas) ï¶Â Ib â non-homogenous but still energetically full (93 coronas)ï¶Â Ic â energetically poor (76 coronas) and 3 types in altered states of consciousness (pictures obtained from dr. Korotkov, recorded by different GDV cameras with different settings of parameters and pictures were not normalized â they were of variable size): ï¶ Â Rings â double coronas (we added 7 pictures of double coronas recorded in Ljubljana) (90 coronas)ï¶ Â Branches â long streamers branching in various directions (74 coronas) ï¶Â Spots â unusual spots (51 coronas) Our aim is to differentiate normal from altered state of consciousness (2 classes) and to differentiate among all 6 types of coronas (6 classes). Figure 1 provides example coronas for each type.
GDV Corona's types 2. The methodology We first had to preprocess all the pictures so that all were of equal size (320 x 240). We then described the pictures with various sets of numerical parameters (attributes) with five different parametrization algorithms (described in more detail in the next section): a) IP (Image Processor â 22 attributes), b) PCA (Principal Component Analysis), c) Association Rules, d) GDV Assistant with some basic GDV parameters, e)GDV Assistant with additional parameters. Therefore we had available 5 different learning sets for two-classes problem: altered (one of Rings, Spots, and Branches) versus non- altered (one of Ia, Ib, Ic) state of consciousness. Some of the sets were used also as six-classes problems (differentiating among all six different types of coronas). We tried to solve some of the above classification tasks by using various machine learning algorithms as implemented in Weka system (Witten and Frank, 2000): ï· Â Quinlan's (1993) C4.5 algorithm for generating decision trees;ï· Â K-nearest neighbor classifier by Aha, D., and D. Kibler (1991);ï· Â Simple Kernel Density classifier;ï· Â NaĂŻve Bayesian classifier using estimator classes: Numeric estimator precision valuesare chosen based on analysis of the training data. For this reason, the classifier is not an Updateable Classifier (which in typical usage are initialized with zero training instances, see (John and Langley, 1995));ï· Â SMO implements John C. Platt's sequential minimal optimization algorithm for training a support vector classifier using polynomial kernels. It transforms the output of SVM Types Ia, Ib and Icâ normal state of consciousness into probabilities by applying a standard sigmoid function that is not fitted to the data. This implementation globally replaces all missing values and transforms nominal attributes into binary ones (see Platt, 1998; Keerthi et al., 2001); ï·Â Neural networks: standard multilayared feedforward neural network with backpropagation of errors learning mechanism (Rumelhart et al., 1986). SMO algorithm can be used only for two-classes problems, while the other algorithms can be used on two-classes and on six-classes problems. Types Branches, Rings and Spotsâ altered states of consciousness Figure 1: Example coronas for each type. Full text PDF: 2004-Kononenko-altered-coronas References Aha, D., and D. Kibler (1991) "Instance-based learning algorithms", Machine Learning, vol.6, pp. 37-66. R. Agrawal, T. Imielinski, and A. Swami (1993) Mining association rules between sets of items in large databases. In P. Buneman and S. Jajodia, editors, Proceedings of the 1993 ACM SIGMOD International Conference on Mangement of Data, pages 207-216, Washington, D.C., 1993. R. Agrawal and R. Srikant (1994) Fast algorithms for mining association rules. In J. B. Bocca, M. Jarke, and C. Zaniolo, editors, Proc. 20th Int. Conf. Very Large Data Bases, VLDB, pages 487-499. Morgan Kaufmann. Bevk M. (2003) Texture Analysis with Machine Learning, M.Sc. Thesis, University of Ljubljana, Faculty of Computer and Information Science, Ljubljana, Slovenia. (in Slovene) Julesz, B., Gilbert, E.N., Shepp, L.A., Frisch H.L.(1973). Inability of Humans To Discriminate Between Visual Textures That Agree in Second-Order-Statistics, Perception 2, pp. 391-405. M. Bevk and I. Kononenko (2002) A statistical approach to texture description: A preliminary study. In ICML-2002 Workshop on Machine Learning in Computer Vision, pages 39-48, Sydney, Australia, 2002. R. Haralick, K. Shanmugam, and I. Dinstein (1973) Textural features for image classification. IEEE Transactions on Systems, Man and Cybernetics, pages 610-621. G. H. John and P. Langley (1995). Estimating Continuous Distributions in Bayesian Classifiers. Proceedings of the Eleventh Conference on Uncertainty in Artificial Intelligence. pp. 338-345. Morgan Kaufmann, San Mateo. S.S. Keerthi, S.K. Shevade, C. Bhattacharyya, K.R.K. Murthy (2001). Improvements to Platt's SMO Algorithm for SVM Classifier Design. Neural Computation, 13(3), pp 637-649, 2001. Korotkov, K. (1998) Aura and Consciousness, St.Petersburg, Russia: State Editing & Publishing Unit âKulturaâ. Korotkov, K., Korotkin, D. (2001) Concentration dependence of gas discharge around drops of inorganic electrolytes, Journal of Applied Physics, Vol. 89, pp. 4732-4736. J. Platt (1998). Fast Training of Support Vector Machines using Sequential Minimal Optimization. Advances in Kernel Methods - Support Vector Learning, B. Schölkopf, C. Burges, and A. Smola, eds., MIT Press. W.H. Press, B.P. Flannery, S.A. Teukolsky, and W.T. Vetterling (1992) Numerical Recipes: The Art of Scientific Computing. Cambridge University Press, Cambridge (UK) and New York, 2ndedition. J.R. Quinlan (1993) C4.5 Programs for Machine Learning, Morgan Kaufmann. D.E. Rumelhart, G.E. Hinton, R.J. Williams (1986) Learning internal representations by error propagation. In: Rumelhart D.E. and McClelland J.L. (eds.) Parallel Distributed Processing, Vol. 1: Foundations. Cambridge: MIT Press. J. A. Rushing, H. S. Ranagath, T. H. Hinke, and S. J. Graves (2001) Using association rules as texture features. IEEE Transactions on Pattern Analysis and Machine Intelligence, pages 845-858. A. Sadikov (2002) Computer visualization, parametrization and analysis of images of electrical gas discgarge (in Slovene), M.Sc. Thesis, University of Ljubljana, 2002. L. Sirovich and M. Kirby (1987) A low-dimensional procedure for the characterisation of human faces. Journal of the Optical Society of America, pages 519-524. A. Sadikov, I. Kononenko, F. Weibel (2003) Analyzing Coronas of Fruits and Leaves, This volume. M. Turk and A. Pentland (1991) Eigenfaces for recognition. Journal of Cognitive Neuroscience, pages 71-86. I. H. Witten, E. Frank (2000) Data mining: Practical machine learning tools and techniques with Java implementations, Morgan Kaufmann. Read the full article
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