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E-raamat: Optomechanical Systems Engineering

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Covers the fundamental principles behind optomechanical design

This book emphasizes a practical, systems-level overview of optomechanical engineering, showing throughout how the requirements on the optical system flow down to those on the optomechanical design. The author begins with an overview of optical engineering, including optical fundamentals as well as the fabrication and alignment of optical components such as lenses and mirrors. The concepts of optomechanical engineering are then applied to the design of optical systems, including the structural design of mechanical and optical components, structural dynamics, thermal design, and kinematic design.

 Optomechanical Systems Engineering:





Reviews the fundamental concepts of optical engineering as they apply to optomechanical design Illustrates the fabrication and alignment requirements typically found in an optical system Examines the elements of structural design from a mechanical, optical, and vibrational viewpoint Develops the thermal management principles of temperature and distortion control Describes the optomechanical requirements for kinematic and semi-kinematic mounts Uses examples and case studies to illustrate the concepts and equations presented in the book Provides supplemental materials on a companion website

Focusing on fundamental concepts and first-order estimates of optomechanical system performance, Optomechanical Systems Engineering is accessible to engineers, scientists, and managers who want to quickly master the principles of optomechanical engineering.

Arvustused

The whole book is written in a very accessible style, and there are plenty of good exercises for the reader. It would be a good resource for engineers and research students entering the field.  (Optics & Photonics News, 4 September 2015)

 

Preface ix
1 Introduction 1(16)
1.1 Optomechanical Systems,
2(2)
1.2 Optomechanical Engineering,
4(5)
1.3 Optomechanical Systems Engineering,
9(6)
References,
15(2)
2 Optical Fundamentals 17(18)
2.1 Geometrical Optics,
18(8)
2.2 Image Quality,
26(7)
Problems,
33(1)
References,
34(1)
3 Optical Fabrication 35(22)
3.1 Index of Refraction,
38(3)
3.2 Surface Curvature,
41(2)
3.3 Surface Figure,
43(5)
3.4 Surface Finish,
48(1)
3.5 Surface Quality,
49(1)
3.6 Center Thickness,
50(1)
3.7 Wedge,
51(2)
3.8 Clear Aperture,
53(1)
Problems,
54(1)
References,
55(2)
4 Optical Alignment 57(20)
4.1 Types of Misalignments,
58(6)
4.1.1 Tilt,
59(2)
4.1.2 Decenter,
61(1)
4.1.3 Despace,
62(1)
4.1.4 Defocus,
62(2)
4.2 Alignment Requirements,
64(2)
4.3 Correction and Mitigation,
66(4)
4.4 Pointing and Boresighting,
70(5)
Problems,
75(1)
References,
76(1)
5 Structural Design-Mechanical Elements 77(30)
5.1 Stress, Strain, and Stiffness,
78(4)
5.2 Mechanics,
82(3)
5.3 Beam Stresses and Strains,
85(10)
5.3.1 Bending Stresses,
86(3)
5.3.2 Bending Strain,
89(5)
5.3.3 Shear Stresses and Strains,
94(1)
5.4 Structural Geometries,
95(4)
5.5 Structural Materials,
99(5)
5.5.1 Specific Stiffness,
100(2)
5.5.2 Microcreep,
102(1)
5.5.3 Materials Selection,
103(1)
Problems,
104(1)
References,
105(2)
6 Structural Design-Optical Components 107(26)
6.1 Structural Plates,
109(13)
6.1.1 Windows, Lenses, and Mirrors,
109(2)
6.1.2 Poisson's Ratio,
111(2)
6.1.3 Plate Bending,
113(2)
6.1.4 Contact Stresses,
115(5)
6.1.5 Stress Concentrations,
120(2)
6.2 Glass Strength,
122(8)
6.2.1 Fracture Toughness,
122(4)
6.2.2 Weibull Statistics,
126(4)
Problems,
130(1)
References,
131(2)
7 Structural Design-Vibrations 133(38)
7.1 Sinusoidal Vibrations,
137(9)
7.1.1 Free Vibrations,
137(3)
7.1.2 Forced Vibrations,
140(2)
7.1.3 Damping,
142(4)
7.2 Random Vibrations,
146(4)
7.3 Continuous Systems,
150(7)
7.4 Structural Design and Materials Selection,
157(2)
7.5 Vibration Isolation,
159(7)
7.6 Vibration Compensation,
166(2)
Problems,
168(1)
References,
169(2)
8 Thermal Design 171(44)
8.1 Thermostructural Design,
173(8)
8.1.1 Thermal Expansion,
173(5)
8.1.2 Thermal Stress,
178(3)
8.2 Thermo-Optic and Stress-Optic Effects,
181(6)
8.2.1 Thermo-Optic Effect,
182(3)
8.2.2 Stress-Optic Effect,
185(2)
8.3 Heat Transfer,
187(14)
8.3.1 Conduction,
187(6)
8.3.2 Convection,
193(3)
8.3.3 Radiation,
196(5)
8.4 Thermal Management,
201(4)
8.4.1 Heaters,
202(1)
8.4.2 Fans,
203(1)
8.4.3 Thermal Interface Materials (TIMs),
203(1)
8.4.4 Thermoelectric Coolers (TECs),
204(1)
8.5 Material Properties and Selection,
205(6)
8.5.1 Thermal Expansion,
206(1)
8.5.2 Thermal Distortion,
207(1)
8.5.3 Thermal Mass,
208(1)
8.5.4 Thermal Diffusivity,
209(1)
8.5.5 Thermal Shock,
210(1)
Problems,
211(1)
References,
212(3)
9 Kinematic Design 215(22)
9.1 Kinematic and Semi-Kinematic Mounts,
216(6)
9.2 Optical Component Mounts,
222(5)
9.3 Positioning and Alignment Mechanisms,
227(6)
9.4 Material Properties and Selection,
233(2)
Problems,
235(1)
References,
235(2)
10 System Design 237(14)
10.1 STOP Analysis,
239(4)
10.2 WFE and Zernike Polynomials,
243(3)
10.3 Material Trades,
246(4)
References,
250(1)
Index 251
Keith J. Kasunic has more than 25 years of experience developing optical, electro-optical, infrared, and laser systems. He holds a Ph.D. in Optical Sciences from the University of Arizona, an MS in Mechanical Engineering from Stanford University, and a BS in Mechanical Engineering from MIT. He is currently the Technical Director of Optical Systems Group LLC. He also teaches courses on optomechanical engineering as an SPIE Instructor, an Affiliate Instructor with Georgia Institute of Technologys SENSIAC, an Instructor for the Optical Engineering Certificate Program at University of CaliforniaIrvine, and an Adjunct Professor at University of Central Floridas CREOL.
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