Handbook of Optical Design, 2nd Edition



Contents
Preface to the Second Edition
Preface to the First Edition
1. Geometrical Optics Principles
1.1 Wave Nature of Light and Fermat’s Principle
1.2 Reflection and Refraction Laws
1.3 Basic Meridional Ray Tracing Equations
1.4 Gaussian or First-Order Optics
1.5 Image Formation
1.6 Stop, Pupils, and Principal Ray
1.7 Optical Sine Theorem
1.8 Herschel Invariant and Image Magnifications
1.9 Ray Aberrations and Wave Aberrations
References
2. Thin Lenses and Spherical Mirrors
2.1 Thin Lenses
2.2 Formulas for Image Formation with Thin Lenses
2.3 Nodal Points of a Thin Lens
2.4 Image Formation with Convergent Lenses
2.5 Image Formation with Divergent Lenses
References
3. Systems of Several Lenses and Thick Lenses
3.1 Focal Length and Power of a Lens System
3.2 Image Formation with Thick Lenses or Systems of Lenses
3.3 Cardinal Points
3.4 Image Formation with a Tilted or Curved Object
3.5 Thick Lenses
3.6 Systems of Thin Lenses
© 2004 by Marcel Dekker, Inc.
3.7 The Lagrange Invariant in a System of Thin Lenses
3.8 Effect of Object or Stop Shifting
3.9 The Delano y–y Diagram
References
4. Spherical Aberration
4.1 Spherical Aberration Calculation
4.2 Primary Spherical Aberration
4.3 Aspherical Surfaces
4.4 Spherical Aberration of Aspherical Surfaces
4.5 Surfaces without Spherical Aberration
4.6 Aberration Polynomial for Spherical Aberration
4.7 High-Order Spherical Aberration
4.8 Spherical Aberration Correction with Gradient Index
References
5. Monochromatic Off-Axis Aberrations
5.1 Oblique Rays
5.2 Petzval Curvature
5.3 Coma
5.4 Astigmatism
5.5 Distortion
5.6 Off-Axis Aberrations in Aspherical Surfaces
5.7 Aberrations and Wavefront Deformations
5.8 Symmetrical Principle
5.9 Stop Shift Equations
References
6. Chromatic Aberrations
6.1 Introduction
6.2 Axial Chromatic Aberration
6.3 Secondary Color Aberration
6.4 Magnification Chromatic Aberration
References
7. The Aberration Polynomial
7.1 Wave Aberration Polynomial
7.2 Zernike Polynomials
7.3 Wavefront Representation by an Array of Gaussians
7.4 Transverse Aberration Polynomials
References
© 2004 by Marcel Dekker, Inc.
8. Diffraction in Optical Systems
8.1 Huygens–Fresnel Theory
8.2 Fresnel Diffraction
8.3 Fraunhofer Diffraction
8.4 Diffraction Images with Aberrations
8.5 Strehl Ratio
8.6 Optical Transfer Function
8.7 Resolution Criteria
8.8 Gaussian Beams
References
9. Computer Evaluation of Optical Systems
9.1 Meridional Ray Tracing and Stop Position Analysis
9.2 Spot Diagram
9.3 Wavefront Deformation
9.4 Point and Line Spread Functions
9.5 Optical Transfer Function
9.6 Tolerance to Aberrations
References
10. Prisms
10.1 Tunnel Diagram
10.2 Deflecting a Light Beam
10.3 Transforming an Image
10.4 Deflecting and Transforming Prisms
10.5 Nondeflecting Transforming Prisms
10.6 Beam-Splitting Prisms
10.7 Chromatic Dispersing Prisms
References
11. Simple Optical Systems and Photographic Lenses
11.1 Optical Systems Diversity
11.2 Single Lens
11.3 Spherical and Paraboloidal Mirrors
11.4 Periscopic Lens
11.5 Achromatic Landscape Lenses
11.6 Achromatic Double Lens
11.7 Some Catoptric and Catadioptric Systems
11.8 Fresnel Lenses and Gabor Plates
References
© 2004 by Marcel Dekker, Inc.
12. Complex Photographic Lenses
12.1 Introduction
12.2 Asymmetrical Systems
12.3 Symmetrical Anastigmat Systems
12.4 Varifocal and Zoom Lenses
References
13. The Human Eye and Ophthalmic Lenses
13.1 The Human Eye
13.2 Ophthalmic Lenses
13.3 Ophthalmic Lens Design
13.4 Prismatic Lenses
13.5 Spherocylindrical Lenses
References
14. Astronomical Telescopes
14.1 Resolution and Light Gathering Power
14.2 Catadioptric Cameras
14.3 Newton Telescope
14.4 Reflecting Two-Mirror Telescopes
14.5 Field Correctors
14.6 Catadioptric Telescopes
14.7 Multiple Mirror Telescopes
14.8 Active and Adaptive Optics
References
15. Visual Systems, Visual Telescopes, and Afocal Systems
15.1 Visual Optical Systems
15.2 Basic Telescopic System
15.3 Afocal Systems
15.4 Refracting Objectives
15.5 Visual and Terrestrial Telescopes
15.6 Telescope Eyepieces
15.7 Relays and Periscopes
References
16. Microscopes
16.1 Compound Microscope
16.2 Microscope Objectives
16.3 Microscope Eyepieces
16.4 Microscope Illuminators
References
© 2004 by Marcel Dekker, Inc.
17. Projection Systems
17.1 Slide and Movie Projectors
17.2 Coherence Effects in Projectors
17.3 Main Projector Components
17.4 Anamorphic Projection
17.5 Overhead Projectors
17.6 Profile Projectors
17.7 Television Projectors
References
18. Lens Design Optimization
18.1 Basic Principles
18.2 Optimization Methods
18.3 Glatzel Adaptive Method
18.4 Constrained Damped Least Squares Optimization
Method
18.5 Merit Function and Boundary Conditions
18.6 Modern Trends in Optical Design
18.7 Flow Chart for a Lens Optimization Program
18.8 Lens Design and Evaluation Programs
18.9 Some Commercial Lens Design Programs
References
Appendix 1. Notation and Primary Aberration Coefficients
Summary
A1.1 Notation
A1.2 Summary of Primary Aberration Coefficients
Appendix 2. Mathematical Representation of Optical Surfaces
A2.1 Spherical and Aspherical Surfaces
References
Appendix 3. Optical Materials
A3.1 Optical Glasses
A3.2 Optical Plastics
A3.3 Infrared and Ultraviolet Materials
Bibliography
Appendix 4. Exact Ray Tracing of Skew Rays
A4.1 Exact Ray Tracing
A4.2 Summary of Ray Tracing Results
© 2004 by Marcel Dekker, Inc.
A4.3 Tracing Through Tilted or Decentered Optical
Surfaces
References
Appendix 5. General Bibliography on Lens Design
© 2004

下载地址：
https://www.rayfile.com/files/8b ... -9cbd-0015c55db73d/，

非常不错！
很实用！