Advances in imaging and electron physics. Volume 171 /

Advances in Imaging and Electron Physics merges two long-running serials--Advances in Electronics and Electron Physics and Advances in Optical and Electron Microscopy. This series features extended articles on the physics of electron devices (especially semiconductor devices), particle optics at hig...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Hawkes, P. W.
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Amsterdam ; Boston : Elsevier/Academic Press, 2012.
Edición:1st ed.
Colección:Advances in imaging and electron physics ; v171
Temas:
Electrons.
Image processing.
Electronics.
Electrons
Electronics
�Electrons.
Traitement d'images.
�Electronique.
image processing.
SCIENCE > Physics > Nuclear.
Image processing
Acceso en línea:Texto completo
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Tabla de Contenidos:
  • Front Cover; Advances in Imaging and Electron Physics; Copyright; Table of Contents; Preface; Contributors; Future Contributions; 1 Derivation of the Reflection Equations for Higher-Order Aberrations of Local Wave Fronts by Oblique Incidence; 1. Introduction; 1.1. Rays, Wave Fronts, and Aberrations; 1.2. Classification of Aberrations; 1.3. Scope of the Work; 2. Definitions and Notation; 2.1. Coordinate Systems; 2.2. Description of Wave Fronts; 2.3. Local Properties of Wave Fronts and Surface; 3. Mathematical Approach in the 2D Case; 3.1. Coordinates in the 2D Case
  • 3.2. Description of Wave Fronts in the 2D Case3.3. Normal Vectors and their Derivatives; 3.4. Ansatz for Determining the Reflection Equations; 3.5. Solving Techniques for the Fundamental Equation; 3.6. Solutions for the General Reflection Equations; 3.7. Generalization of the Coddington Equation; 4. Mathematical Approach in the 3D Case; 4.1. Wave Fronts and Normal Vectors; 4.2. Ansatz for Determining the Reflection Equations; 4.3. Solutions for the General Reflection Equations; 4.4. Generalization of the Coddington Equation; 5. Results and Discussion; 5.1. The 2D Case; 5.2. The 3D Case
  • 6. Examples and Applications6.1. Aspherical Surface Correction Up to Sixth Order; 6.2. Special Examples; 6.2.1. Spherical Mirror; 6.2.2. Parabolic Mirror; 6.2.3. Plane Mirror; 6.3. A Numerical Example; 7. Summary; References; 2 Thermal Imaging in Medicine; 1. Introduction; 2. The Physics Behind Thermal Imaging; 3. Medical Thermal Imaging; 4. Physiological Modeling of Heat Flow in Thermal Image Analysis; 5. Infrared Thermal Imaging in the Detection and Diagnosis of Various Medical Problems; 5.1. Tumor and Breast Cancer Detection; 5.2. Raynaud's Phenomenon; 5.3. Assessment of Pain
  • 5.3.1. Diseases of the Skeletal and Neuromuscular Systems5.3.2. Headache and Migraine; 5.4. Vascular Disorders; 5.5. Anxiety, Stress, and Sleep Apnea; 6. Data-Processing Methods Used in the Analysis of Medical Thermograms; 6.1. Solving the Inverse Problem; 6.2. Extracting Indicators from Thermogram Images; 6.2.1. Image Segmentation for ROI Detection; 6.2.2. Asymmetry-Based Features; 6.2.3. Other Features; 6.2.4. Classification Methods; 6.3. Discussion on the Merits and Demerits of the Two Approaches; 7. Conclusions; Acknowledgments; References
  • 3 Derivation of the Radiative Transfer Equation in a Medium with a Spatially Varying Refractive Index: A Review1. The Radiative Transfer Equation; 1.1. Introduction; 1.2. Derivation of a Radiative Transfer Equation; 1.3. Phase-Space Representation; 2. Energy Conservation; 2.1. Energy Conservation Equation; 2.2. The Laws of Geometrical Optics; 2.3. The Inverse Square Law; 3. Hamiltonian Formulation of Radiative Transfer; 3.1. Hamiltonian for Ray Optics; 3.2. Reformulation of the Radiative Transfer Equation; 4. The Diffusion Approximation; 5. Conclusion; References

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