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The Resource Integrated optomechanical analysis, Keith B. Doyle, Victor L. Genberg, Gregory J. Michels, (electronic book)

Integrated optomechanical analysis, Keith B. Doyle, Victor L. Genberg, Gregory J. Michels, (electronic book)

Label
Integrated optomechanical analysis
Title
Integrated optomechanical analysis
Statement of responsibility
Keith B. Doyle, Victor L. Genberg, Gregory J. Michels
Creator
Contributor
Subject
Language
eng
Summary
This tutorial presents optomechanical modeling techniques to effectively design and analyze high-performance optical systems. It discusses thermal and structural modeling methods that use finite-element analysis to predict the integrity and performance of optical elements and optical support structures. Includes accompanying CD-ROM with examples
Member of
Additional physical form
Also available in print version.
Cataloging source
CaBNvSL
http://library.link/vocab/creatorName
Doyle, Keith B.
Dewey number
681/.4
Illustrations
illustrations
Index
index present
LC call number
TS513
LC item number
.D69 2002e
Literary form
non fiction
Nature of contents
  • dictionaries
  • bibliography
http://library.link/vocab/relatedWorkOrContributorName
  • Michels, Gregory J.
  • Genberg, Victor L.
  • Society of Photo-optical Instrumentation Engineers
Series statement
Tutorial texts in optical engineering
Series volume
TT58
http://library.link/vocab/subjectName
Optical instruments
Target audience
  • adult
  • specialized
Label
Integrated optomechanical analysis, Keith B. Doyle, Victor L. Genberg, Gregory J. Michels, (electronic book)
Instantiates
Publication
Note
  • "SPIE digital library."
  • Title from PDF t.p. (viewed on August 22, 2009)
Bibliography note
Includes bibliographical references and index
Color
black and white
Contents
  • Introduction -- Chapter 1. Introduction to Mechanical Analysis Using Finite Elements -- 1.1 Integrated Optomechanical Analysis Issues -- 1.2 Elasticity Review -- 1.3 Basics of Finite Element Analysis -- 1.4 Symmetry in FE models -- 1.5 Stress Analysis -- 1.6 Vibrations -- 1.7 Model Checkout -- 1.8 Summary -- References --
  • Chapter 2. Optical Basics and Zernike Polynomials -- 2.1 Electromagnetic Basics -- 2.2 Polarization -- 2.3 Rays, Wavefronts, and Wavefront Error -- 2.4 Image Quality and Optical Performance -- 2.5 Image Formation -- 2.6 Zernike Polynomials -- 2.7 Legendre-Fourier Polynomials -- 2.8 Aspheric and x-y Polynomials -- References --
  • Chapter 3. Optomechanical Displacement Analysis Methods -- 3.1 Displacement Models of Optics. 3.2 Displacement Models of Adhesive Bonds. 3.3 Displacement Models of Flexures and Mounts -- 3.4 Displacement Analysis Methods -- References --
  • Chapter 4. Integration of Optomechanical Analyses -- 4.1 Optical Surface Positional Errors -- 4.2 Optical Surface Shape Changes -- 4.3 Line-of-Sight Jitter -- 4.4 Stress Birefringence -- 4.5 Mechanical Obscurations -- References --
  • Chapter 5 Optothermal Analysis Methods -- 5.1. Thermo-Elastic Analysis -- 5.2 Thermo-Optic Analysis -- 5.3 Effects of Temperature on Optical System Performance -- 5.4 Optical Design Software -- 5.5 Thermo-Optic Finite Element Models -- 5.6 Bulk Volumetric Absorption -- 5.7 Mapping of Temperature Fields from the Thermal Model to the Structural Model -- 5.8 Analogous Techniques -- References --
  • Chapter 6. Adaptive Optics Analysis Methods -- 6.1 Introduction -- 6.2 Method of Simulation -- 6.3 Coupled Adaptive Control Simulation and Structural Design Optimization -- References --
  • Chapter 7. Optimization of Optomechanical Systems -- 7.1 Overview -- 7.2 Optimization Theory -- 7.3 Structural Optimization, Including Optical Measures -- 7.4 Integrated Thermal-Structural-Optical Optimization -- References --
  • Chapter 8. Integrated Optomechanical Analysis of a Telescope -- 8.1 Overview -- 8.2 Optical Model Description -- 8.3 Structural Model Description -- 8.4 One-Gravity Static Performance -- 8.5 On-Orbit Image Motion Random Response -- 8.6 Optimizing PMA with Optical Measures -- 8.7 Adaptive PM -- 8.8 System-level Multidisciplinary Optimization -- References --
  • Chapter 9. Integrated Optomechanical Analysis of a Lens Assembly -- 9.1 Overview -- 9.2 Thermal Analysis -- 9.3 Thermo-elastic Analysis -- 9.4 Stress Birefringence Analysis -- 9.5 Thermo-Optic Analysis -- 9.6 Optical Analysis -- Index
Dimensions
unknown
Extent
1 online resource (xiv, 231 p. : ill.)
File format
multiple file formats
Form of item
electronic
Isbn
9780819478658
Other physical details
digital file.
Reformatting quality
access
Reproduction note
Electronic resource.
Specific material designation
remote
System details
System requirements: Adobe Acrobat Reader
Label
Integrated optomechanical analysis, Keith B. Doyle, Victor L. Genberg, Gregory J. Michels, (electronic book)
Publication
Note
  • "SPIE digital library."
  • Title from PDF t.p. (viewed on August 22, 2009)
Bibliography note
Includes bibliographical references and index
Color
black and white
Contents
  • Introduction -- Chapter 1. Introduction to Mechanical Analysis Using Finite Elements -- 1.1 Integrated Optomechanical Analysis Issues -- 1.2 Elasticity Review -- 1.3 Basics of Finite Element Analysis -- 1.4 Symmetry in FE models -- 1.5 Stress Analysis -- 1.6 Vibrations -- 1.7 Model Checkout -- 1.8 Summary -- References --
  • Chapter 2. Optical Basics and Zernike Polynomials -- 2.1 Electromagnetic Basics -- 2.2 Polarization -- 2.3 Rays, Wavefronts, and Wavefront Error -- 2.4 Image Quality and Optical Performance -- 2.5 Image Formation -- 2.6 Zernike Polynomials -- 2.7 Legendre-Fourier Polynomials -- 2.8 Aspheric and x-y Polynomials -- References --
  • Chapter 3. Optomechanical Displacement Analysis Methods -- 3.1 Displacement Models of Optics. 3.2 Displacement Models of Adhesive Bonds. 3.3 Displacement Models of Flexures and Mounts -- 3.4 Displacement Analysis Methods -- References --
  • Chapter 4. Integration of Optomechanical Analyses -- 4.1 Optical Surface Positional Errors -- 4.2 Optical Surface Shape Changes -- 4.3 Line-of-Sight Jitter -- 4.4 Stress Birefringence -- 4.5 Mechanical Obscurations -- References --
  • Chapter 5 Optothermal Analysis Methods -- 5.1. Thermo-Elastic Analysis -- 5.2 Thermo-Optic Analysis -- 5.3 Effects of Temperature on Optical System Performance -- 5.4 Optical Design Software -- 5.5 Thermo-Optic Finite Element Models -- 5.6 Bulk Volumetric Absorption -- 5.7 Mapping of Temperature Fields from the Thermal Model to the Structural Model -- 5.8 Analogous Techniques -- References --
  • Chapter 6. Adaptive Optics Analysis Methods -- 6.1 Introduction -- 6.2 Method of Simulation -- 6.3 Coupled Adaptive Control Simulation and Structural Design Optimization -- References --
  • Chapter 7. Optimization of Optomechanical Systems -- 7.1 Overview -- 7.2 Optimization Theory -- 7.3 Structural Optimization, Including Optical Measures -- 7.4 Integrated Thermal-Structural-Optical Optimization -- References --
  • Chapter 8. Integrated Optomechanical Analysis of a Telescope -- 8.1 Overview -- 8.2 Optical Model Description -- 8.3 Structural Model Description -- 8.4 One-Gravity Static Performance -- 8.5 On-Orbit Image Motion Random Response -- 8.6 Optimizing PMA with Optical Measures -- 8.7 Adaptive PM -- 8.8 System-level Multidisciplinary Optimization -- References --
  • Chapter 9. Integrated Optomechanical Analysis of a Lens Assembly -- 9.1 Overview -- 9.2 Thermal Analysis -- 9.3 Thermo-elastic Analysis -- 9.4 Stress Birefringence Analysis -- 9.5 Thermo-Optic Analysis -- 9.6 Optical Analysis -- Index
Dimensions
unknown
Extent
1 online resource (xiv, 231 p. : ill.)
File format
multiple file formats
Form of item
electronic
Isbn
9780819478658
Other physical details
digital file.
Reformatting quality
access
Reproduction note
Electronic resource.
Specific material designation
remote
System details
System requirements: Adobe Acrobat Reader

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