OPTICAL SYSTEM DESIGNThis classic resource provides a clear, well-illustrated introduction to the essentials of optical design-from basic principles to cutting-edge design methods. |
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Contents
1 | |
27 | |
35 | |
49 | |
Chapter 5 Review of Specific Geometrical Aberrations and How to Get Rid of Them | 61 |
Chapter 6 Glass Selection Including Plastics | 95 |
Chapter 7 Spherical and Aspheric Surfaces | 115 |
Chapter 8 Design Forms | 129 |
Chapter 15 Performance Evaluation and Optical Testing | 301 |
Chapter 16 Tolerancing and Producibility | 315 |
Chapter 17 Optical Manufacturing Considerations | 357 |
Chapter 18 Polarization Issues In Optical Design | 387 |
Chapter 19 Optical Thin Films | 421 |
Chapter 20 Hardware Design Issues | 439 |
Chapter 21 Lens Design Optimization Case Studies | 457 |
Chapter 22 Bloopers and Blunders in Optics | 513 |
Chapter 9 The Optical Design Process | 167 |
Chapter 10 Computer Performance Evaluation | 181 |
Chapter 11 Gaussian Beam Imagery | 203 |
Chapter 12 Basics of Thermal Infrared Imaging in the 3 to 5 and 8 to 12956m Spectral Bands Plus UV Optics | 217 |
Chapter 13 Diffractive Optics | 263 |
Chapter 14 Design of Illumination Systems | 289 |
Chapter 23 Rules of Thumb and Hints | 531 |
Glossary | 537 |
Bibliography | 547 |
Index | 551 |
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Common terms and phrases
achromatic angle aperture aperture stop applications approximately aspheric beam blur called camera coating cold color components consider correction cost curves diameter diffraction direction discussed distance distortion doublet edge effect efficiency element energy error example extremely field of view Figure final focal length focus function given glass important incidence increase laser lateral lens lenses less light limited located look lower magnification manufacturing material means measured mirror Note object optical axis optical system optimization parameters perfect performance plane plate polarization position primary prism problem radius range reason reduced reflected refractive refractive index relative represent result retardance scan shape shown in Fig shows similar space specifications spectral spherical aberration surface telescope temperature thermal thickness tion tolerances trace wave wavefront wavelength