書籍 | レンズ
商品コード:
9780819491640
Field Guide to Lens Design
販売価格(税込):
4,830
円
ポイント:
48
Pt
Julie Bentley; Craig Olson
156 pages; Spiral Bound
2012/12/7
FG27
詳細
The process of designing lenses is both an art and a science. While advancements in the field over the past two centuries have done much to transform it from the former category to the latter, much of the lens design process remains encapsulated in the experience and knowledge of industry veterans. This Field Guide provides a working reference for practicing physicists, engineers, and scientists for deciphering the nuances of basic lens design.
Sample Pages(PDF)
Glossary of Symbols and Acronyms
Fundamentals of Optical Design
Sign Conventions
Basic Concepts
Optical Design Process
Aperture and Wavelength Specifications
Resolution and Field of View
Packaging and Environment
Wave Aberration Function
Third-Order Aberration Theory
Spot Diagram and Encircled Energy
Transverse Ray Plot
Wavefront or OPD Plots
Point Spread Function and Strehl Ratio
MTF Basics
Using MTF in Lens Design
Defocus
Wavefront Tilt
Spherical Aberration
Coma
Field Curvature
Petzval Curvature
Astigmatism
Distortion
Primary Color and Secondary Color
Lateral Color and Spherochromatism
Higher-Order Aberrations
Intrinsic and Induced Aberrations
Design Forms
Selecting a Design Form: Refractive
Selecting a Design Form: Reflective
Singlets
Achromatic Doublets
Airspaced Doublets
Cooke Triplet
Double Gauss
Petzval Lens
Telephoto Lenses
Retrofocus and Wide-Angle Lenses
Refractive versus Reflective Systems
Obscurations
Newtonian and Cassegrain
Gregorian and Schwarzschild
Catadioptric Telescope Objectives
Unobscured Systems: Aperture Clearance
Unobscured Systems: Field Clearance
Three-Mirror Anastigmat
Reflective Triplet
Wide-Field Reflective Design Forms
Zoom Lens Fundamentals
Zoom Lens Design and Optimization
Improving a Design
Techniques for Improving an Optical Design
Angle of Incidence and Aplanatic Surfaces
Splitting and Compounding
Diffraction-Limited Performance
Thin Lens Layout
Lens Bending
Material Selection
Controlling the Petzval Sum
Stop Shift and Stop Symmetry
Telecentricity
Vignetting
Pupil Aberrations
Aspheres: Design
Aspheres: Fabrication
Gradient Index Materials
Diffractive Optics
Optimization
Optimization
Damped Least Squares
Global Optimization
Merit Function Construction
Choosing Effective Variables
Solves and Pickups
Defining Field Points
Pupil Sampling
Tolerancing
Tolerancing
Design Margin and Performance Budgets
Optical Prints
Radius of Curvature Tolerances
Surface Irregularity
Center Thickness and Wedge Tolerances
Material and Cosmetic Tolerances
Lens Assembly Methods
Assembly Tolerances
Compensators
Probability Distributions
Sensitivity Analysis
Performance Prediction
Monte Carlo Analysis
Environmental Analysis
Athermalization
Stray Light
Stray Light Analysis
Stray Light Reduction
Antireflection (AR) Coatings
Ghost Analysis
Cold Stop and Narcissus
Nonsequential Ray Tracing
Scattering and BSDF
Optical Systems
Photographic Lenses: Fundamentals
Photographic Lenses: Design Constraints
Visual Instruments and the Eye
Eyepiece Fundamentals
Eyepiece Design Forms
Telescopes
Microscopes
Microscope Objectives
Relays
Appendix: Optical Fundamentals
Index of Refraction and Dispersion
Optical Materials: Glasses
Optical Materials: Polymers/Plastics
Optical Materials: Ultraviolet and Infrared
Snell's Law and Ray Tracing
Focal Length, Power, and Magnification
Aperture Stop and Field Stop
Entrance and Exit Pupils
Marginal and Chief Rays
Zernike Polynomials
Conic Sections
Diffraction Gratings
Optical Cements and Coatings
Detectors: Sampling
Detectors: Resolution
The Lagrange Invariant and Etendue
Illumination Design
Equation Summary
Bibliography
Index
