Describes the optimization methods commonly encountered in signal and image processing: artificial evolution and Parisian approach; wavelets and fractals; information criteria; training and quadratic programming; Bayesian formalism; probabilistic modeling; Markovian approach; hidden Markov models; and, metaheuristics.

Introduction xiii Chapter 1. Modeling and Optimization in Image Analysis 1 Jean Louchet 1.1. Modeling at the source of image analysis and synthesis 1 1.2. From image synthesis to analysis 2 1.3. Scene geometric modeling and image synthesis 3 1.4. Direct model inversion and the Hough transform 4 1.5. Optimization and physical modeling 9 1.6. Conclusion 12 1.7. Acknowledgements 13 1.8. Bibliography 13 Chapter 2. Artificial Evolution and the Parisian Approach. Applications in the Processing of Signals and Images 15 Pierre Collet and Jean Louchet 2.1. Introduction 15 2.2. The Parisian approach for evolutionary algorithms 15 2.3. Applying the Parisian approach to inverse IFS problems 17 2.4. Results obtained on the inverse problems of IFS 20 2.5. Conclusion on the usage of the Parisian approach for inverse IFS problems 22 2.6. Collective representation: the Parisian approach and the Fly algorithm 23 2.7. Conclusion 40 2.8. Acknowledgements 41 2.9.Bibliography 41 Chapter 3. Wavelets and Fractals for Signal and Image Analysis 45 Abdeldjalil Ouahabi and Djedjiga Ait Aouit 3.1. Introduction 45 3.2. Some general points on fractals 46 3.3. Multifractal analysis of signals 54 3.4. Distribution of singularities based on wavelets 60 3.5. Experiments 70 3.6. Conclusion 76 3.7. Bibliography 76 Chapter 4. Information Criteria: Examples of Applications in Signal and Image Processing 79 Christian Oliver and Olivier Alata 4.1. Introduction and context 79 4.2. Overview of the different criteria 81 4.3. The case of auto-regressive (AR) models 83 4.4. Applying the process to unsupervised clustering 95 4.5. Law approximation with the help of histograms 98 4.6. Other applications 103 4.7. Conclusion 106 4.8. Appendix 106 4.9. Bibliography 107 Chapter 5. Quadratic Programming and Machine Learning – Large Scale Problems and Sparsity 111 Gaëlle Looslil, Stéphane Canu 5.1. Introduction 111 5.2. Learning processes and optimization 112 5.3. From learning methods to quadratic programming 117 5.4. Methods and resolution 119 5.5. Experiments 128 5.6. Conclusion 132 5.7. Bibliography 133 Chapter 6. Probabilistic Modeling of Policies and Application to Optimal Sensor Management 137 Frédéric Dambreville, Francis Celeste and Cécile Simonin 6.1. Continuum, a path toward oblivion 137 6.2. The cross-entropy (CE) method 138 6.3. Examples of implementation of CE for surveillance 146 6.4. Example of implementation of CE for exploration 153 6.5. Optimal control under partial observation 158 6.6. Conclusion 166 6.7. Bibliography 166 Chapter 7. Optimizing Emissions for Tracking and Pursuit of Mobile Targets 169 Jean-Pierre Le Cadre 7.1. Introduction 169 7.2. Elementary modeling of the problem (deterministic case) 170 7.3. Application to the optimization of emissions (deterministic case) 175 7.4. The case of a target with a Markov trajectory 181 7.5. Conclusion 189 7.6. Appendix: monotonous functional matrices 189 7.7. Bibliography 192 Chapter 8. Bayesian Inference and Markov Models 195 Christophe Collet 8.1. Introduction and application framework 195 8.2. Detection, segmentation and classification 196 8.3. General modeling 199 8.4. Segmentation using the causal-in-scale Markov model 201 8.5. Segmentation into three classes 203 8.6. The classification of objects 206 8.7. The classification of seabeds 212 8.8. Conclusion and perspectives 214 8.9. Bibliography 215 Chapter 9. The Use of Hidden Markov Models for Image Recognition: Learning with Artificial Ants, Genetic Algorithms and Particle Swarm Optimization 219 Sébastien Aupetit, Nicolas Monmarchè and Mohamed Slimane 9.1. Introduction 219 9.2. Hidden Markov models (HMMs) 220 9.3. Using metaheuristics to learn HMMs 223 9.4. Description, parameter setting and evaluation of the six approaches that are used to train HMMs 226 9.5. Conclusion 240 9.6. Bibliography 240 Chapter 10. Biological Metaheuristics for Road Sign Detection 245 Guillaume Dutilleux and Pierre Charbonnier 10.1. Introduction 245 10.2. Relationship to existing works 246 10.3. Template and deformations 248 10.4. Estimation problem 248 10.5. Three biological metaheuristics 252 10.6. Experimental results 259 10.7. Conclusion 265 10.8. Bibliography 266 Chapter 11. Metaheuristics for Continuous Variables. The Registration of Retinal Angiogram Images 269 Johann Drèo, Jean-Claude Nunes and Patrick Siarry 11.1. Introduction 269 11.2. Metaheuristics for difficult optimization problems 270 11.3. Image registration of retinal angiograms 275 11.4. Optimizing the image registration process 279 11.5. Results 288 11.6. Analysis of the results 295 11.7. Conclusion 296 11.8. Acknowledgements 296 11.9. Bibliography 296 Chapter 12. Joint Estimation of the Dynamics and Shape of Physiological Signals through Genetic Algorithms 301 Amine Naït-Ali and Patrick Siarry 12.1. Introduction 301 12.2. Brainstem Auditory Evoked Potentials (BAEPs) 302 12.3. Processing BAEPs 303 12.4. Genetic algorithms 305 12.5. BAEP dynamics 307 12.6. The non-stationarity of the shape of the BAEPs 324 12.7. Conclusion 327 12.8. Bibliography 327 Chapter 13. Using Interactive Evolutionary Algorithms to Help Fit Cochlear Implants 329 Pierre Collet, Pierrick Legrand, Claire Bourgeois-République, Vincent Péan and Bruno Frachet 13.1. Introduction 329 13.2. Choosing an optimization algorithm 333 13.3. Adapting an evolutionary algorithm to the interactive fitting of cochlear implants 335 13.4. Evaluation 338 13.5. Experiments 339 13.6. Medical issues which were raised during the experiments 350 13.7. Algorithmic conclusions for patient A 352 13.8. Conclusion 354 13.9. Bibliography 354 List of Authors 357 Index 359