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BL
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880762
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| Main Entry
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Dilworth, Donald
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| Title & Author
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Lens design : : automatic and quasi-autonomous computational methods and techniques /\ Donald Dilworth.
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| Publication Statement
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Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) :: IOP Publishing,, [2018]
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| Series Statement
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IOP expanding physics,
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Series in emerging technologies in optics and photonics
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| Page. NO
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1 online resource :: illustrations (some color).
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| ISBN
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0750316098
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: 0750316101
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: 075031611X
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: 9780750316095
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: 9780750316101
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: 9780750316118
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9780750316095
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| Notes
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"Version: 20180701"--Title page verso.
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| Bibliographies/Indexes
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Includes bibliographical references.
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| Contents
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1. Preliminaries -- 1.1. Why is lens design hard? -- 1.2. How to use this book
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10. Third-order aberrations -- 10.1. Tolerance desensitization -- 11. The in and out of vignetting -- 12. The apochromat
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13. Tolerancing the apochromatic objective -- 13.1. Fabrication adjustment -- 13.2. Transferring tolerances to element drawings
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14. A near-infrared lens example -- 14.1. Design approach -- 15. A laser beam shaper, all spherical -- 16. A laser beam shaper, with aspherics -- 17. A laser beam expander with kinoform lenses
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18. A more challenging optimization challenge -- 18.1. Glass absorption -- 19. Real-world development of a lens
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2. Fundamentals -- 2.1. Paraxial optics -- 2.2. Lagrange invariant, thin-lens equation -- 2.3. Pupils
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20. A practical camera lens -- 20.1. Reusing dialog commands -- 21. An automatic real-world lens
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22. What is a good pupil? -- 22.1. Which way is up? -- 23. Using DOEs in modern lens design
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24. Designing aspheres for manufacturing -- 24.1. Adding unusual requirements to the merit function with CLINK -- 24.2. Defining an aberration with COMPOSITE -- 25. Designing an athermal lens -- 26. Using the SYNOPSYS glass model -- 27. Chaos in lens optimization -- 28. Tolerance example with clocking of element wedge errors and AI analysis of an image error -- 29. Tips and tricks of a power user
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3. Aberrations -- 3.1. Ray-fan curves -- 3.2. Abbe sine condition -- 3.3. Higher-order aberrations -- 3.4. Spot diagrams -- 3.5. Wavefronts and aberrations : the OPD -- 3.6. Chromatic aberration
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30. FLIR design, the narcissus effect -- 30.1. Narcissus correction
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31. Understanding artificial intelligence -- 31.1. Error correction -- 31.2. MACro loops -- 32. The Annotation Editor
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33. Understanding Gaussian beams -- 33.1. Gaussian beams in SYNOPSYS -- 33.2. Complications -- 33.3. Beam profile -- 33.4. Effect on image -- 34. The superachromat
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35. Wide-band superachromat microscope objective -- 35.1. Vector diffraction, polarization -- 36. Ghost hunting -- 37. Importing a Zemax file into SYNOPSYS -- 38. Improving a Petzval lens -- 39. Athermalizing an infrared lens
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4. Using a modern lens design code -- 4.1. Using the software -- 4.2. The process of lens design
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40. Edges -- 40.1. A mirror example -- 41. A 90 degree eyepiece with field stop correction -- 42. A zoom lens from scratch -- 43. Designing a free-form mirror system
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44. An aspheric camera lens from scratch -- 44.1. Encore -- 44.2 Coda -- 44.3. Tolerancing the aspheric lenses -- 45. Designing a very wide-angle lens -- 46. A complex interferometer -- 47. A four-element astronomical telescope -- 48. A sophisticated merit function
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49. When automatic methods do not apply -- 49.1. The 'final exam' problem -- 49.2. The solution
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5. The singlet lens -- 5.1. Entering data for the singlet -- 6. Achromatizing the lens -- 7. PSD optimization
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50. Other automatic methods -- 50.1. Testplate matching -- 50.2. Automatic thin-film design -- 50.3. Automatic clocking of wedge errors
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8. The amateur telescope -- 8.1. The Newtonian telescope -- 8.2. The Schmidt-Cassegrain telescope -- 8.3. The relay telescope -- 8.4. How good is good enough? -- 9. Improving a lens designed using a different lens design program
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Appendices. A. A brief history of computer-aided lens design -- B. Optimization methods -- C. The mathematics of lens tolerances -- D. Things every lens designer should understand -- E. Useful formulas.
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| Abstract
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Lens Design: Automatic and Quasi-Autonomous Computational Methods and Techniques is the first book that interactively describes the newest modern lens design tools. Detailing design methods for a variety of lens forms, this book shows that fixed focus and zoom lenses can be optimized, starting from plane-parallel surfaces, in a brief time on a modern fast PC compared to traditional tools that require many days or weeks of tedious work. Loaded with tips and ideas resulting from over 50 years of experience, the reader will improve their lens design skill. Experienced and aspiring lens designers who master the power of the tools, methods, and principles taught in this book will be able to develop excellent designs now and in the future. Part of Series in Emerging Technologies in Optics and Photonics.
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| Subject
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Lenses.
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Optical instruments.
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Lenses.
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Optical instruments.
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Physics.
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SCIENCE / Physics / Astrophysics.
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| Dewey Classification
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681/.423
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| LC Classification
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TS517.3.D555 2018eb
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| Added Entry
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Institute of Physics (Great Britain),publisher.
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