Optical imaging and spectroscopy
An essential reference for optical sensor system design This is the first text to present an integrated view of the optical and mathematical analysis tools necessary to understand computational optical system design. It presents the foundations of computational optical sensor design with a focus ent...
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| Format: | eBook |
| Language: | Inglés |
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Hoboken, N.J. :
Wiley
c2008.
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| Edition: | 1st edition |
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| See on Biblioteca Universitat Ramon Llull: | https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009627699406719 |
Table of Contents:
- OPTICAL IMAGING AND SPECTROSCOPY; CONTENTS; Preface; Acknowledgments; Acronyms; 1 Past, Present, and Future; 1.1 Three Revolutions; 1.2 Computational Imaging; 1.3 Overview; 1.4 The Fourth Revolution; Problems; 2 Geometric Imaging; 2.1 Visibility; 2.2 Optical Elements; 2.3 Focal Imaging; 2.4 Imaging Systems; 2.5 Pinhole and Coded Aperture Imaging; 2.6 Projection Tomography; 2.7 Reference Structure Tomography; Problems; 3 Analysis; 3.1 Analytical Tools; 3.2 Fields and Transformations; 3.3 Fourier Analysis; 3.4 Transfer Functions and Filters; 3.5 The Fresnel Transformation
- 3.6 The Whittaker-Shannon Sampling Theorem3.7 Discrete Analysis of Linear Transformations; 3.8 Multiscale Sampling; 3.9 B-Splines; 3.10 Wavelets; Problems; 4 Wave Imaging; 4.1 Waves and Fields; 4.2 Wave Model for Optical Fields; 4.3 Wave Propagation; 4.4 Diffraction; 4.5 Wave Analysis of Optical Elements; 4.6 Wave Propagation Through Thin Lenses; 4.7 Fourier Analysis of Wave Imaging; 4.8 Holography; Problems; 5 Detection; 5.1 The Optoelectronic Interface; 5.2 Quantum Mechanics of Optical Detection; 5.3 Optoelectronic Detectors; 5.3.1 Photoconductive Detectors; 5.3.2 Photodiodes
- 5.4 Physical Characteristics of Optical Detectors5.5 Noise; 5.6 Charge-Coupled Devices; 5.7 Active Pixel Sensors; 5.8 Infrared Focal Plane Arrays; Problems; 6 Coherence Imaging; 6.1 Coherence and Spectral Fields; 6.2 Coherence Propagation; 6.3 Measuring Coherence; 6.3.1 Measuring Temporal Coherence; 6.3.2 Spatial Interferometry; 6.3.3 Rotational Shear Interferometry; 6.3.4 Focal Interferometry; 6.4 Fourier Analysis of Coherence Imaging; 6.4.1 Planar Objects; 6.4.2 3D Objects; 6.4.3 The Defocus Transfer Function; 6.5 Optical Coherence Tomography; 6.6 Modal Analysis; 6.6.1 Modes and Fields
- 6.6.2 Modes and Coherence Functions6.6.3 Modal Transformations; 6.6.4 Modes and Measurement; 6.7 Radiometry; 6.7.1 Generalized Radiance; 6.7.2 The Constant Radiance Theorem; Problems; 7 Sampling; 7.1 Samples and Pixels; 7.2 Image Plane Sampling on Electronic Detector Arrays; 7.3 Color Imaging; 7.4 Practical Sampling Models; 7.5 Generalized Sampling; 7.5.1 Sampling Strategies and Spaces; 7.5.2 Linear Inference; 7.5.3 Nonlinear Inference and Group Testing; 7.5.4 Compressed Sensing; Problems; 8 Coding and Inverse Problems; 8.1 Coding Taxonomy; 8.2 Pixel Coding; 8.2.1 Linear Estimators
- 8.2.2 Hadamard Codes8.3 Convolutional Coding; 8.4 Implicit Coding; 8.5 Inverse Problems; 8.5.1 Convex Optimization; 8.5.2 Maximum Likelihood Methods; Problems; 9 Spectroscopy; 9.1 Spectral Measurements; 9.2 Spatially Dispersive Spectroscopy; 9.3 Coded Aperture Spectroscopy; 9.4 Interferometric Spectroscopy; 9.5 Resonant Spectroscopy; 9.6 Spectroscopic Filters; 9.6.1 Volume Holographic Filters; 9.6.2 Thin-Film Filters; 9.7 Tunable Filters; 9.7.1 Liquid Crystal Tunable Filters; 9.7.2 Acoustooptic Tunable Filters; 9.8 2D Spectroscopy; 9.8.1 Coded Apertures and Digital Superresolution
- 9.8.2 Echelle Spectroscopy
