Diffractive Optics Design Fabrication and Test TT62 1st edition by Donald OShea, Thomas Suleski, Alan Kathman, Dennis Prather – Ebook PDF Instant Download/Delivery: 0819451711, 9780819451712
Full download Diffractive Optics Design Fabrication and Test TT62 1st edition after payment
Product details:
ISBN 10: 0819451711
ISBN 13: 9780819451712
Author: Donald C. O’Shea, Thomas J. Suleski, Alan D. Kathman, Dennis W. Prather
Diffractive Optics Design Fabrication and Test TT62 1st Table of contents:
Chapter 1: Introduction
1.1 Where Do Diffractive Elements Fit in Optics?
1.2 A Quick Survey of Diffractive Optics
1.3 A Classic Optical Element: The Fresnel Lens
1.4 Light Treated as a Propagating Wave
1.5 A Physical Optics Element: The Blazed Grating
1.6 Fanout Gratings
1.6.1 Designing a Fanout Grating
1.7 Constructing the Profile: Optical Lithography
1.8 A Theme
Chapter 2: Scalar Diffraction Theory
2.1 Rayleigh-Sommerfeld Propagation
2.2 Fourier Analysis
2.2.1 The Dirac Delta Function
2.2.2 The Convolution Theorem
2.3 Using Fourier Analysis
2.4 Diffraction Efficiency of Binary Optics
2.4.1 The Square-Wave Grating
2.4.2 Approximating the Blazed Grating
2.5 Extended Scalar Theory
2.6 Conclusion
References
Chapter 3: Electromagnetic Analysis of Diffractive Optical Elements
3.1 Scalar Limitations
3.2 Plane-Wave Spectrum Method
3.3 Electromagnetic Diffraction Models
3.3.1 Modal Method
3.3.2 Finite-Difference Time-Domain Method
3.4 Effective Media Theory
References
Chapter 4: Diffractive Lens Design
4.1 Basics of Lens Design
4.1.1 Describing an Optical System
4.1.2 The Lensmaker’s Equation
4.1.3 Chromatic Aberration
4.1.4 Third-Order Errors
4.1.5 Ray Intercept Curves
4.2 Diffractive Optics Lens Design
4.2.1 The Diffractive Lens
4.2.2 The Phase Profile
4.2.3 Generating a Single-Element Design
4.2.4 Design of a Kinoform Lens
4.2.5 A Simplification
4.3 Efficiency of Multilevel Diffractive Lenses
4.3.1 At Other Wavelengths
4.3.2 Efficiency of Diffractive Lenses
4.3.3 A Diffractive Optics Lens and Its Limitations
4.4 Hybrid Lenses
4.4.1 Correcting Chromatic Aberration with Diffractive Surfaces
4.4.2 Entering a Singlet
4.4.3 Example: Diffractive Surface on a Quartz Window
4.4.4 Combining Refractive and Diffractive Surfaces
References
Chapter 5: Design of Diffraction Gratings
5.1 Introduction
5.1.1 Splitting a Wavefront
5.1.2 A 1×3 Grating
5.1.3 Complex Fanouts
5.2 Design Approaches
5.3 Design Variables
5.4 Direct Inversion
5.5 Iterative Design
5.5.1 Bidirectional Algorithms
5.5.2 Simulated Annealing
5.5.3 Genetic Algorithms
5.6 Conclusion
References
Chapter 6: Making a DOE
6.1 The Profile
6.2 Photolithography: A Method for DOE Fabrication
6.3 From Equation to Component
6.3.1 Converting Function to Form
6.3.2 Example: 1×2 Beam Splitter
6.3.3 Mask Generation
6.4 Interplay Between Fabrication and Optical Design
6.4.1 Optical Functionality
6.4.2 Fabrication Constraints
6.4.3 Effects of Thin-Film Coatings
6.4.4 Materials
6.5 Facilities and Substrates
6.5.1 Clean Rooms and DOE Fabrication
6.5.2 Substrate Testing and Cleaning
6.6 Fabrication of DOEs
References
Chapter 7: Photolithographic Fabrication of Diffractive Optical Elements
7.1 Photolithographic Processing
7.1.1 Photoresist Coatings
7.1.2 Spin Coating Photoresist
7.1.3 Exposure and Development
7.1.4 Etching
7.2 Binary Optics
7.3 Conclusion
References
Chapter 8: Survey of Fabrication Techniques for Diffractive Optical Elements
8.1 Lithographic Techniques
8.1.1 Direct Writing
8.1.2 Interferometric Exposure
8.1.3 Gray-Scale Lithography
8.1.4 Near-Field Holography
8.1.5 Refractive Micro-Optics
8.2 Direct Machining
8.2.1 Mechanical Ruling
8.2.2 Diamond Turning
8.2.3 Other Methods of Direct Machining
8.3 Replication
8.3.1 Plastic Injection Molding
8.3.2 Thermal Embossing
8.3.3 Casting and UV Embossing
8.3.4 Soft Lithography
8.4 Comparison of Fabrication Methods for DOEs
References
Chapter 9: Testing Diffractive Optical Elements
9.1 Metrology
9.1.1 Optical Microscopy
9.1.2 Mechanical Profilometry
9.1.3 Atomic Force Microscopy
9.1.4 Scanning Electron Microscopy
9.1.5 Phase-Shifting Interferometry
9.2 Testing Optical Performance
9.2.1 Scatterometer
9.2.2 Charge-Coupled Device
9.2.3 Rotating Slit Scanners
9.2.4 Array Testing
9.3 Effects of Fabrication Errors on DOE Performance
References
Chapter 10: Application of Diffractive Optics to Lens Design
10.1 Introduction
10.1.1 The Aberrations of a Diffractive Lens
10.1.2 Adapting Optical Design for Diffractive Elements: The Sweatt Model
10.2 Diffractive Lenses
10.2.1 The F Lens
10.2.2 Landscape Lens
10.2.3 Diffractive Telescopes
10.2.4 Superzone Lenses
10.2.5 Staircase Lenses
10.3 Hybrid Lenses
10.3.1 Infrared Objectives
10.3.2 Infrared Telescopes
10.3.3 Eyepieces
10.4 Thermal Compensation with Diffractive Optics
10.4.1 Coefficient of Thermal Defocus
10.4.2 Thermal Effects on a Mounted Lens
10.4.3 Hybrid Lens and Mount
References
Chapter 11: Additional Applications of Diffractive Optical Elements
11.1 Introduction
11.2 Multiple Lens Applications
11.2.1 Lens Arrays for Optical Coupling
11.2.2 Microlenses for Beam Steering
11.2.3 Lens Arrays for Sensors
11.2.4 Beam Homogenizers
11.3 Beam-Shaping Applications
11.3.1 Focusing Beam Shapers
11.3.2 Laser Resonator Design
11.4 Grating Applications
11.4.1 Beam Deflectors, Splitters, and Samplers
11.4.2 Spot Array Generators
11.4.3 Talbot Array Illuminators
11.4.4 Controlled-Angle Diffusers
11.5 Subwavelength Gratings
11.5.1 Anti-Reflection Surfaces and Wavelength Filters
11.5.2 Wave Plates
11.5.3 Subwavelength Diffraction Gratings and Lenses
11.6 Integration and Modules
11.7 Example Application Area: Optical Communications
11.7.1 Data Communications versus Telecommunications
11.7.2 Example: Parallel Hybrid Array for Data Communications
11.8 Conclusion
People also search for Diffractive Optics Design Fabrication and Test TT62 1st:
optical fabrication and testing
diffractive optics design fabrication and test pdf
j d optical
optical specification fabrication and testing
Reviews
There are no reviews yet.