Engineering optics 2.0 : a revolution in optical theories, materials, devices and systems /: a revolution in optical theories, materials, devices and systems. ([2019])
- Record Type:
- Book
- Title:
- Engineering optics 2.0 : a revolution in optical theories, materials, devices and systems /: a revolution in optical theories, materials, devices and systems. ([2019])
- Main Title:
- Engineering optics 2.0 : a revolution in optical theories, materials, devices and systems
- Further Information:
- Note: Xiangang Luo.
- Authors:
- Luo, Xiangang
- Contents:
- Intro; Foreword; Preface; Contents; 1 Introduction to Engineering Optics 2.0; 1.1 Definition of Engineering Optics 2.0; 1.2 Basics of Engineering Optics 1.0; 1.2.1 Historical and Theoretical Remarks; 1.2.2 Material Basis; 1.2.3 Design Methods; 1.2.4 Manufacturing Technologies; 1.3 Great Challenges of EO 1.0; 1.3.1 Diffraction Optics; 1.3.2 Refractive and Reflective Optics; 1.3.3 Optical Absorption; 1.3.4 Polarization Optics; 1.3.5 Radiation and Emission; 1.4 Opportunities Enabled by Subwavelength Structures; 1.4.1 Emergence of Subwavelength Structures; 1.4.2 Sub-diffraction Optics 1.4.3 Planar Optics1.4.4 Modulation of Polarization Properties; 1.4.5 Strategies for Dispersion Engineering; 1.5 The Third Optical Revolution; 1.6 Overview of the Book; References; 2 Theoretical Basis; 2.1 Theories and Laws in Classic Optics; 2.1.1 From Fermat's Principle to Snell's Law and Fresnel's Equations; 2.1.2 From Kirchhoff's Diffraction Theory to the Diffraction Limit; 2.1.3 Absorption and Radiation Theory; 2.2 Macroscopic and Microscopic Meta-surface-wave; 2.2.1 Theory of Surface Plasmon Polariton; 2.2.2 Spoof Surface Plasmon Polariton 2.2.3 Catenary Optical Fields and Catenary Dispersion2.3 Generalized Laws of Refraction and Reflection; 2.3.1 Extending Snell's Law and Fresnel's Equations; 2.3.2 Propagation Phase Engineering; 2.3.3 Circuit-Type Phase Engineering; 2.3.4 Geometric Phase Engineering; 2.4 Generalized Theory of Diffraction; 2.4.1 Sub-diffraction-Limited Optics with EvanescentIntro; Foreword; Preface; Contents; 1 Introduction to Engineering Optics 2.0; 1.1 Definition of Engineering Optics 2.0; 1.2 Basics of Engineering Optics 1.0; 1.2.1 Historical and Theoretical Remarks; 1.2.2 Material Basis; 1.2.3 Design Methods; 1.2.4 Manufacturing Technologies; 1.3 Great Challenges of EO 1.0; 1.3.1 Diffraction Optics; 1.3.2 Refractive and Reflective Optics; 1.3.3 Optical Absorption; 1.3.4 Polarization Optics; 1.3.5 Radiation and Emission; 1.4 Opportunities Enabled by Subwavelength Structures; 1.4.1 Emergence of Subwavelength Structures; 1.4.2 Sub-diffraction Optics 1.4.3 Planar Optics1.4.4 Modulation of Polarization Properties; 1.4.5 Strategies for Dispersion Engineering; 1.5 The Third Optical Revolution; 1.6 Overview of the Book; References; 2 Theoretical Basis; 2.1 Theories and Laws in Classic Optics; 2.1.1 From Fermat's Principle to Snell's Law and Fresnel's Equations; 2.1.2 From Kirchhoff's Diffraction Theory to the Diffraction Limit; 2.1.3 Absorption and Radiation Theory; 2.2 Macroscopic and Microscopic Meta-surface-wave; 2.2.1 Theory of Surface Plasmon Polariton; 2.2.2 Spoof Surface Plasmon Polariton 2.2.3 Catenary Optical Fields and Catenary Dispersion2.3 Generalized Laws of Refraction and Reflection; 2.3.1 Extending Snell's Law and Fresnel's Equations; 2.3.2 Propagation Phase Engineering; 2.3.3 Circuit-Type Phase Engineering; 2.3.4 Geometric Phase Engineering; 2.4 Generalized Theory of Diffraction; 2.4.1 Sub-diffraction-Limited Optics with Evanescent Waves; 2.4.2 Sub-diffraction-Limited Optics Without Evanescent Waves; 2.5 Generalized Theory of Absorption and Radiation; 2.5.1 Generalized Absorption Theory; 2.5.2 Generalized Radiation Theory; References; 3 Material Basis 3.1 Introduction3.2 Natural Materials; 3.2.1 Metals; 3.2.2 Refractory Plasmonic Materials; 3.2.3 Semiconductors; 3.2.4 Dielectric Materials; 3.2.5 Phase Transition and Phase-Change Materials; 3.2.6 Flexible Substrate Materials; 3.2.7 Two-Dimensional Materials and van der Waals Materials; 3.2.8 Perovskite Materials; 3.3 Artificially Structured Materials; 3.3.1 Effective Medium Theory; 3.3.2 Negative-Index Materials; 3.3.3 Near-Zero Index Materials; 3.3.4 Ultra-High Index Materials; 3.3.5 Hyperbolic Metamaterials; References; 4 Numerical Modeling and Intelligent Designs; 4.1 Introduction 4.2 Design Methods for Multilayers and Gratings4.2.1 Transfer Matrix Method; 4.2.2 Rigorous Coupled-Wave Analysis; 4.3 Full-Wave Simulation Methods; 4.3.1 FDTD; 4.3.2 FEM; 4.4 Optimizing Algorithms; 4.4.1 Holographic Algorithms; 4.4.2 Nature-Inspired Optimization Methods; 4.4.3 Other Optimizing Algorithms; 4.5 Intelligent Design and All-Optical Implementation; 4.5.1 Intelligent Design Models; 4.5.2 All-Optical Implementation; References; 5 Fabrication Techniques; 5.1 Status and Challenges of Manufacturing Techniques for EO 1.0; 5.1.1 Manufacture of Refractive and Reflective Optical Elements … (more)
- Publisher Details:
- Singapore : Springer
- Publication Date:
- 2019
- Extent:
- 1 online resource
- Subjects:
- 621.36
Optical engineering
TECHNOLOGY & ENGINEERING / Mechanical
Electronic books - Languages:
- English
- ISBNs:
- 9789811357558
9811357552 - Related ISBNs:
- 9811357544
9789811357541 - Notes:
- Note: Description based on online resource; title from digital title page (viewed on March 21, 2019).
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- British Library HMNTS - ELD.DS.399969
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